1839302
UVN4N32C
2023
surface-science-reports
50
creator
asc
18349
https://www.ipcms.fr/wp-content/plugins/zotpress/
%7B%22status%22%3A%22success%22%2C%22updateneeded%22%3Afalse%2C%22instance%22%3A%22zotpress-2b4debb3fcbcb534bdb232202d6283bb%22%2C%22meta%22%3A%7B%22request_last%22%3A0%2C%22request_next%22%3A0%2C%22used_cache%22%3Atrue%7D%2C%22data%22%3A%5B%7B%22key%22%3A%22PTWCIU22%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Acevedo-Salas%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EU.%20Acevedo-Salas%2C%20B.%20Croes%2C%20Y.%20Zhang%2C%20O.%20Cr%26%23xE9%3Bgut%2C%20K.D.%20Dorkenoo%2C%20B.%20Kirbus%2C%20E.%20Singh%2C%20H.%20Beccard%2C%20M.%20Rusing%2C%20L.M.%20Eng%2C%20R.%20Hertel%2C%20E.A.%20Eliseev%2C%20A.N.%20Morozovska%2C%20S.%20Cherifi-Hertel%2C%20Impact%20of%203D%20Curvature%20on%20the%20Polarization%20Orientation%20in%20Non-Ising%20Domain%20Walls.%2C%20Nano%20Letters%2023%20%282023%29%20795%26%23x2013%3B803.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facs.nanolett.2c03579%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facs.nanolett.2c03579%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Impact%20of%203D%20Curvature%20on%20the%20Polarization%20Orientation%20in%20Non-Ising%20Domain%20Walls.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ulises%22%2C%22lastName%22%3A%22Acevedo-Salas%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Boris%22%2C%22lastName%22%3A%22Croes%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yide%22%2C%22lastName%22%3A%22Zhang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Olivier%22%2C%22lastName%22%3A%22Cr%5Cu00e9gut%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Kokou%20Dodzi%22%2C%22lastName%22%3A%22Dorkenoo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Benjamin%22%2C%22lastName%22%3A%22Kirbus%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ekta%22%2C%22lastName%22%3A%22Singh%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Henrik%22%2C%22lastName%22%3A%22Beccard%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Michael%22%2C%22lastName%22%3A%22Rusing%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Lukas%20M%22%2C%22lastName%22%3A%22Eng%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Riccardo%22%2C%22lastName%22%3A%22Hertel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Eugene%20A%22%2C%22lastName%22%3A%22Eliseev%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anna%20N%22%2C%22lastName%22%3A%22Morozovska%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Salia%22%2C%22lastName%22%3A%22Cherifi-Hertel%22%7D%5D%2C%22abstractNote%22%3A%22Ferroelectric%20domain%20boundaries%20are%20quasi-two-dimensional%20functional%20interfaces%20with%20high%20prospects%20for%20nanoelectronic%20applications.%20Despite%20their%20reduced%20dimensionality%2C%20they%20can%20exhibit%20complex%20non-Ising%20polarization%20configurations%20and%20unexpected%20physical%20properties.%20Here%2C%20the%20impact%20of%20the%20three-dimensional%20%283D%29%20curvature%20on%20the%20polarization%20profile%20of%20nominally%20uncharged%20180%5Cu00b0%20domain%20walls%20in%20LiNbO3%20is%20studied%20using%20second-harmonic%20generation%20microscopy%20and%203D%20polarimetry%20analysis.%20Correlations%20between%20the%20domain-wall%20curvature%20and%20the%20variation%20of%20its%20internal%20polarization%20unfold%20in%20the%20form%20of%20modulations%20of%20the%20Neel-like%20character%2C%20which%20we%20attribute%20to%20the%20flexoelectric%20effect.%20While%20the%20Neel-like%20character%20originates%20mainly%20from%20the%20tilting%20of%20the%20domain%20wall%2C%20the%20internal%20polarization%20adjusts%20its%20orientation%20due%20to%20the%20synergetic%20upshot%20of%20dipolar%20and%20monopolar%20bound%20charges%20and%20their%20variation%20with%20the%203D%20curvature.%20Our%20results%20show%20that%20curved%20interfaces%20in%20solid%20crystals%20may%20offer%20a%20rich%20playground%20for%20tailoring%20nanoscale%20polar%20states.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1021%5C%2Facs.nanolett.2c03579%22%2C%22ISSN%22%3A%221530-6992%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1021%5C%2Facs.nanolett.2c03579%22%2C%22collections%22%3A%5B%22CHW2VGSR%22%2C%22DEB5KWFS%22%2C%22MKAFAH44%22%2C%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22WWGPR7DV%22%2C%22TBP4QFHK%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A00%3A27Z%22%7D%7D%2C%7B%22key%22%3A%222CJBRT7C%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Ahmed%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EN.%20Ahmed%2C%20R.%20Deffley%2C%20B.%20Kundys%2C%20N.A.%20Morley%2C%203D%20printing%20of%20magnetostrictive%20property%20in%2017%5C%2F4%20ph%20stainless%20steel%2C%20Journal%20of%20Magnetism%20and%20Magnetic%20Materials%20585%20%282023%29%20171115.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.jmmm.2023.171115%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.jmmm.2023.171115%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%223D%20printing%20of%20magnetostrictive%20property%20in%2017%5C%2F4%20ph%20stainless%20steel%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22N.%22%2C%22lastName%22%3A%22Ahmed%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22R.%22%2C%22lastName%22%3A%22Deffley%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22N.%20A.%22%2C%22lastName%22%3A%22Morley%22%7D%5D%2C%22abstractNote%22%3A%22Additive%20manufacturing%20%28AM%29%20of%20metallic%20alloys%20significantly%20advances%20diverse%20areas%20of%20science%5C%2Fengineering%20with%20a%20prosperous%20future%20trend.%20Although%20this%20technology%20is%20also%20very%20attractive%20for%20smart%20materials%20development%2C%20the%20creation%20of%20a%20pre-programmed%20%5C%224th%20dimension%5C%22%20property%20to%20appear%20in%20response%20to%20external%20stimuli%20represents%20an%20important%20challenge.%20Here%20we%20report%20on%203D%20printing%20of%20stainless%20steel%20based%20magnetic%20alloy%20and%20detail%20the%20ways%20to%20optimize%20the%20magnetisation%20and%20magnetostriction%20to%20be%20used%20for%20actuation%20and%20sensing.%20By%20controlling%20the%20printing%20parameters%20and%20sintering%20process%2C%20we%20are%20able%20to%20tune%20the%20magnetic%20and%20magnetoelastic%20properties%20of%20the%2017%5C%2F4%20ph%20stainless%20steel%2C%20demonstrating%20material%20fabrication%20multi-function%20with%20a%20cost%20effective%20advantage.%20The%20stainless%20steel%2017%5C%2F4%20ph%20samples%20in%20the%20as-printed%20%28AP%29%20and%20sintered%20steel%20%28SS%29%20stages%20are%20compared.%20In%20the%20developed%20SS%20sample%2C%20a%20remarkable%20increase%20of%2018%25%20in%20saturation%20magnetisation%20yet%20with%2012.6%20%25%20lower%20coercivity%20was%20achieved.%20Moreover%2C%20the%2054%25%20higher%20magnetostriction%20was%20developed%20for%20the%20SS%20sample%20compared%20to%20the%20AP%20sample.%20Plus%2C%20the%20difference%20in%20anisotropy%20energy%20K1%20was%20also%20lower%20for%20the%20SS%20sample.%20The%20structural%20and%20magnetic%20properties%20control%20are%20reported%20at%20each%20stage%20of%20the%20printing%20process%2C%20demonstrating%20development%20and%20optimization%20prospects%20of%203D%20printable%20metallic%20sensors%20and%20actuators.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1016%5C%2Fj.jmmm.2023.171115%22%2C%22ISSN%22%3A%220304-8853%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1016%5C%2Fj.jmmm.2023.171115%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A15%3A53Z%22%7D%7D%2C%7B%22key%22%3A%229NUMDZIQ%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Ali%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EB.A.%20Ali%2C%20A.%20Bouhmouche%2C%20L.%20Wendling%2C%20C.%20Hu%2C%20C.%20Bouillet%2C%20G.%20Schmerber%2C%20A.M.%20Saeedi%2C%20S.%20Zafeiratos%2C%20V.%20Papaefthimiou%2C%20R.%20Moubah%2C%20S.%20Colis%2C%20Impact%20of%20film%20thickness%20on%20the%20structural%2C%20linear%20and%20non-linear%20optical%20properties%20of%20ferroelectric%20Bi2FeCrO6%20perovskite%20thin%20films%2C%20Vacuum%20216%20%282023%29%20112411.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.vacuum.2023.112411%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.vacuum.2023.112411%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Impact%20of%20film%20thickness%20on%20the%20structural%2C%20linear%20and%20non-linear%20optical%20properties%20of%20ferroelectric%20Bi2FeCrO6%20perovskite%20thin%20films%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22B.%20Ait%22%2C%22lastName%22%3A%22Ali%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22A.%22%2C%22lastName%22%3A%22Bouhmouche%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22L.%22%2C%22lastName%22%3A%22Wendling%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22C.%22%2C%22lastName%22%3A%22Hu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Corinne%22%2C%22lastName%22%3A%22Bouillet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guy%22%2C%22lastName%22%3A%22Schmerber%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22A.%20M.%22%2C%22lastName%22%3A%22Saeedi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22S.%22%2C%22lastName%22%3A%22Zafeiratos%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V.%22%2C%22lastName%22%3A%22Papaefthimiou%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22R.%22%2C%22lastName%22%3A%22Moubah%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Silviu%22%2C%22lastName%22%3A%22Colis%22%7D%5D%2C%22abstractNote%22%3A%22Bi2FeCrO6%20thin%20films%20were%20grown%20by%20PLD%20with%20different%20thicknesses.%20X-ray%20diffraction%20shows%20that%20the%20samples%20are%20epitaxial.%20The%20Williamson-Hall%20equation%20indicates%20that%20the%20microstrain%20diminishes%20with%20increasing%20film%20thickness%2C%20i.e.%2C%20the%20upsurge%20in%20relaxation.%20The%20chemical%20composition%20and%20the%20distribution%20of%20elements%20inside%20the%20films%20were%20investigated%20using%20TEM-EDS.%20The%20measurements%20suggest%20the%20existence%20of%20cationic%20%28Fe%2C%20Cr%29%20ordered%20regions%20with%20relaxed%20lattices%20while%20the%20Fe-Cr%20disordered%20regions%20are%20strained%20due%20to%20the%20substrate.%20The%20valences%20of%20Fe%20and%20Cr%20determined%20by%20XPS%20measurements%20indicate%20that%20both%20cations%20have%20mainly%20a%203%2B%20valence.%20The%20gap%20band%20energy%20decreases%20from%202.25%20to%201.85%20eV%20with%20the%20rise%20of%20thickness%2C%20which%20was%20attributed%20to%20the%20film%20relaxation.%20To%20validate%20the%20Eg%20decrease%20with%20relaxation%2C%20we%20used%20ab%20initio%20calculations%20based%20on%20DFT.%20Its%20shows%20that%20Eg%20indeed%20depends%20on%20the%20variation%20of%20the%20lattice%20parameter%20and%20decreases%20with%20increasing%20lattice%20parameter%20in%20line%20with%20relaxation.%20Urbach%20energy%2C%20refractive%20index%2C%20dielectric%20coefficient%2C%20and%20optical%20conductivity%20were%20extracted%20and%20linked%20to%20structure%20relaxation.%20We%20determined%20the%20non-linear%20optical%20parameters%20such%20as%20the%20energy%20of%20the%20oscillator%2C%20dispersion%20energy%2C%20static%20refraction%20index%20and%20third-order%20nonlinear%20optical%20susceptibility%20as%20a%20function%20of%20film%20thickness.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1016%5C%2Fj.vacuum.2023.112411%22%2C%22ISSN%22%3A%220042-207X%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1016%5C%2Fj.vacuum.2023.112411%22%2C%22collections%22%3A%5B%22DEB5KWFS%22%2C%22UVN4N32C%22%2C%22WJDNKBGA%22%2C%22ZN5EITAC%22%2C%22CF4ZI7HM%22%2C%22SB8Q592R%22%5D%2C%22dateModified%22%3A%222023-11-17T14%3A24%3A28Z%22%7D%7D%2C%7B%22key%22%3A%22M5FCS44C%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Allard%20and%20Weick%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ET.F.%20Allard%2C%20G.%20Weick%2C%20Multiple%20polaritonic%20edge%20states%20in%20a%20Su-Schrieffer-Heeger%20chain%20strongly%20coupled%20to%20a%20multimode%20cavity%2C%20Physical%20Review%20B%20108%20%282023%29%20245417.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.245417%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.245417%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Multiple%20polaritonic%20edge%20states%20in%20a%20Su-Schrieffer-Heeger%20chain%20strongly%20coupled%20to%20a%20multimode%20cavity%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Thomas%20F.%22%2C%22lastName%22%3A%22Allard%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guillaume%22%2C%22lastName%22%3A%22Weick%22%7D%5D%2C%22abstractNote%22%3A%22A%20dimerized%20chain%20of%20dipolar%20emitters%20strongly%20coupled%20to%20a%20multimode%20optical%20waveguide%20cavity%20is%20studied.%20By%20integrating%20out%20the%20photonic%20degrees%20of%20freedom%20of%20the%20cavity%2C%20the%20system%20is%20recast%20in%20a%20two-band%20model%20with%20an%20effective%20coupling%2C%20so%20that%20it%20mimics%20a%20variation%20of%20the%20paradigmatic%20Su-Schrieffer-Heeger%20model%2C%20which%20features%20a%20nontrivial%20topological%20phase%20and%20hosts%20topological%20edge%20states.%20In%20the%20strong-coupling%20regime%2C%20the%20cavity%20photons%20hybridize%20the%20bright%20dipolar%20bulk%20band%20into%20a%20polaritonic%20one%2C%20renormalizing%20the%20eigenspectrum%20and%20strongly%20breaking%20chiral%20symmetry.%20This%20leads%20to%20a%20formal%20loss%20of%20the%20in-gap%20edge%20states%20present%20in%20the%20topological%20phase%20while%20they%20merge%20into%20the%20polaritonic%20bulk%20band.%20Interestingly%2C%20however%2C%20we%20find%20that%20bulk%20polaritons%20entering%20in%20resonance%20with%20the%20edge%20states%20inherit%20part%20of%20their%20localization%20properties%2C%20so%20that%20multiple%20polaritonic%20edge%20states%20are%20observed.%20Although%20these%20states%20are%20not%20fully%20localized%20on%20the%20edges%2C%20they%20present%20unusual%20properties.%20In%20particular%2C%20due%20to%20their%20delocalized%20bulk%20part%2C%20owing%20from%20their%20polaritonic%20nature%2C%20such%20edge%20states%20exhibit%20efficient%20edge-to-edge%20transport%20characteristics.%20Instead%20of%20being%20degenerate%2C%20they%20occupy%20a%20large%20portion%20of%20the%20spectrum%2C%20allowing%20one%20to%20probe%20them%20in%20a%20wide%20driving%20frequency%20range.%20Moreover%2C%20being%20reminiscent%20of%20symmetry-protected%20topological%20edge%20states%2C%20they%20feature%20a%20strong%20tolerance%20to%20positional%20disorder.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.108.245417%22%2C%22ISSN%22%3A%222469-9950%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1103%5C%2FPhysRevB.108.245417%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22EPW69HFA%22%5D%2C%22dateModified%22%3A%222024-09-10T14%3A57%3A30Z%22%7D%7D%2C%7B%22key%22%3A%22E5DKP73Z%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Bowen%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20Bowen%2C%20Atom-level%20electronic%20physicists%20are%20needed%20to%20develop%20practical%20engines%20with%20a%20quantum%20advantage%2C%20NPJ%20Quantum%20Information%209%20%282023%29%201%26%23x2013%3B3.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41534-023-00692-x%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41534-023-00692-x%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Atom-level%20electronic%20physicists%20are%20needed%20to%20develop%20practical%20engines%20with%20a%20quantum%20advantage%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Martin%22%2C%22lastName%22%3A%22Bowen%22%7D%5D%2C%22abstractNote%22%3A%22Theoretical%20research%20into%20quantum%20information%20engines%20that%20surpass%20the%20classical%20Carnot%20limit%20has%20exploded%20these%20past%2010%20years%2C%20but%20experiments%20so%20far%20have%20almost%20exclusively%20been%20the%20realm%20of%20the%20optics%20community.%20To%20help%20advance%20the%20field%2C%20and%20to%20develop%20solutions%20that%20might%20help%20our%20energy-dependent%20global%20society%20navigate%20the%20planetary%20crises%2C%20it%27s%20high%20time%20that%20physicists%20working%20on%20atom-level%20electronics%20join%20the%20game.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1038%5C%2Fs41534-023-00692-x%22%2C%22ISSN%22%3A%222056-6387%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1038%5C%2Fs41534-023-00692-x%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22TR4ZUX8B%22%2C%22IUWT6S8X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A03%3A07Z%22%7D%7D%2C%7B%22key%22%3A%22N8F5TGQV%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Cavallo%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20Cavallo%2C%20E.%20Bossavit%2C%20S.%20Matzen%2C%20T.%20Maroutian%2C%20R.%20Alchaar%2C%20T.H.%20Dang%2C%20A.%20Khalili%2C%20C.%20Dabard%2C%20H.%20Zhang%2C%20Y.%20Prado%2C%20C.%20Abadie%2C%20J.K.%20Utterback%2C%20J.F.%20Dayen%2C%20M.G.G.%20Silly%2C%20P.%20Dudin%2C%20J.%20Avila%2C%20E.%20Lhuillier%2C%20D.%20Pierucci%2C%20Coupling%20Ferroelectric%20to%20colloidal%20Nanocrystals%20as%20a%20Generic%20Strategy%20to%20Engineer%20the%20Carrier%20Density%20Landscape%2C%20Advanced%20Functional%20Materials%20%282023%29%202300846.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1002%5C%2Fadfm.202300846%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1002%5C%2Fadfm.202300846%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Coupling%20Ferroelectric%20to%20colloidal%20Nanocrystals%20as%20a%20Generic%20Strategy%20to%20Engineer%20the%20Carrier%20Density%20Landscape%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mariarosa%22%2C%22lastName%22%3A%22Cavallo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Erwan%22%2C%22lastName%22%3A%22Bossavit%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sylvia%22%2C%22lastName%22%3A%22Matzen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Thomas%22%2C%22lastName%22%3A%22Maroutian%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Rodolphe%22%2C%22lastName%22%3A%22Alchaar%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tung%20Huu%22%2C%22lastName%22%3A%22Dang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Adrien%22%2C%22lastName%22%3A%22Khalili%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Corentin%22%2C%22lastName%22%3A%22Dabard%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Huichen%22%2C%22lastName%22%3A%22Zhang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoann%22%2C%22lastName%22%3A%22Prado%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Claire%22%2C%22lastName%22%3A%22Abadie%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22James%20K.%22%2C%22lastName%22%3A%22Utterback%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean%20Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mathieu%20G.%20G.%22%2C%22lastName%22%3A%22Silly%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Pavel%22%2C%22lastName%22%3A%22Dudin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jose%22%2C%22lastName%22%3A%22Avila%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Emmanuel%22%2C%22lastName%22%3A%22Lhuillier%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Debora%22%2C%22lastName%22%3A%22Pierucci%22%7D%5D%2C%22abstractNote%22%3A%22The%20design%20of%20infrared%20nanocrystals-based%20%28NCs%29%20photodiodes%20faces%20a%20major%20challenge%20related%20to%20the%20identification%20of%20barriers%20with%20a%20well-suited%20band%20alignment%20or%20strategy%20to%20finely%20control%20the%20carrier%20density.%20Here%2C%20this%20study%20explores%20a%20general%20complementary%20approach%20where%20the%20carrier%20density%20control%20is%20achieved%20by%20coupling%20an%20NC%20layer%20to%20a%20ferroelectric%20material.%20The%20up-and-down%20change%20in%20ferroelectric%20polarization%20directly%20impacts%20the%20NC%20electronic%20structure%2C%20resulting%20in%20the%20formation%20of%20a%20lateral%20pn%20junction.%20This%20effect%20is%20uncovered%20directly%20using%20nano%20X-ray%20photoemission%20spectroscopy%2C%20which%20shows%20a%20relative%20energy%20shift%20of%20115%20meV%20of%20the%20NC%20photoemission%20signal%20over%20the%20two%20different%20up-%20and%20down-polarized%20ferroelectric%20regions%2C%20a%20shift%20as%20large%20as%20the%20open%20circuit%20value%20obtained%20in%20the%20diode%20stack.%20The%20performance%20of%20this%20pn%20junction%20reveals%20enhanced%20responsivity%20and%20reduced%20noise%20that%20lead%20to%20a%20factor%2040%20increase%20in%20the%20detectivity%20value.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1002%5C%2Fadfm.202300846%22%2C%22ISSN%22%3A%221616-301X%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1002%5C%2Fadfm.202300846%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A15%3A58Z%22%7D%7D%2C%7B%22key%22%3A%22638GFV33%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Cavallo%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20Cavallo%2C%20A.%20Ram%2C%20S.%20Pandey%2C%20T.%20Maroutian%2C%20E.%20Bossavit%2C%20N.%20Ledos%2C%20A.%20Khalili%2C%20H.%20Zhang%2C%20Y.%20Prado%2C%20D.L.%20Nguyen%2C%20T.H.%20Dang%2C%20H.%20Majjad%2C%20J.%20Biscaras%2C%20J.%20Avila%2C%20J.F.%20Dayen%2C%20E.%20Lhuillier%2C%20D.%20Pierucci%2C%20Using%20wafer%20scale%20ferroelectric%20domains%20of%20LiNbO3%20to%20form%20permanent%20planar%20p-n%20junction%20in%20narrow%20band%20gap%20nanocrystals%2C%20Applied%20Physics%20Letters%20123%20%282023%29%20253505.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0183277%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0183277%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Using%20wafer%20scale%20ferroelectric%20domains%20of%20LiNbO3%20to%20form%20permanent%20planar%20p-n%20junction%20in%20narrow%20band%20gap%20nanocrystals%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mariarosa%22%2C%22lastName%22%3A%22Cavallo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ankita%22%2C%22lastName%22%3A%22Ram%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Satakshi%22%2C%22lastName%22%3A%22Pandey%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Thomas%22%2C%22lastName%22%3A%22Maroutian%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Erwan%22%2C%22lastName%22%3A%22Bossavit%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Nicolas%22%2C%22lastName%22%3A%22Ledos%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Adrien%22%2C%22lastName%22%3A%22Khalili%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Huichen%22%2C%22lastName%22%3A%22Zhang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoann%22%2C%22lastName%22%3A%22Prado%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Do%20Lam%22%2C%22lastName%22%3A%22Nguyen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tung%20Huu%22%2C%22lastName%22%3A%22Dang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hicham%22%2C%22lastName%22%3A%22Majjad%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Johan%22%2C%22lastName%22%3A%22Biscaras%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jose%22%2C%22lastName%22%3A%22Avila%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean%20Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Emmanuel%22%2C%22lastName%22%3A%22Lhuillier%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Debora%22%2C%22lastName%22%3A%22Pierucci%22%7D%5D%2C%22abstractNote%22%3A%22p-n%20junctions%20based%20on%20nanocrystals%20now%20serve%20as%20fundamental%20components%20in%20optoelectronics.%20However%2C%20the%20process%20of%20designing%20these%20p-n%20junctions%20has%20largely%20relied%20on%20empirical%20choices%2C%20either%20for%20ligand%20exchange%20or%20for%20the%20selection%20of%20charge%20transport%20layers.%20Therefore%2C%20a%20systematic%20strategy%20is%20still%20lacking.%20In%20this%20study%2C%20we%20explore%20the%20utilization%20of%20ferroelectric%20domains%20as%20a%20general%20method%20for%20remotely%20inducing%20the%20formation%20of%20a%20p-n%20junction.%20To%20ensure%20compatibility%20with%20devices%20of%20various%20designs%2C%20we%20employ%20a%20commercially%20available%20periodically%20poled%20LiNbO3%20%28PPLN%29%20substrate%20commonly%20used%20in%20nonlinear%20optics.%20We%20engineer%20a%20PPLN%5C%2Fgraphene%5C%2FHgTe%20heterostructure%20and%20demonstrate%20its%20planar%20photodiode%20behavior.%20Through%20x-ray%20photoemission%20microscopy%2C%20we%20confirm%20that%20the%20rectifying%20behavior%20stems%20from%20the%20influence%20of%20the%20ferroelectric%20domains%2C%20by%20ruling%20out%20the%20possibility%20of%20the%20formation%20of%20non-ohmic%20contacts%20at%20the%20electrode%5C%2Fsemiconductor%20interfaces.%20This%20approach%20proves%20to%20be%20quite%20general%20and%20holds%20promise%20for%20the%20future%20design%20of%20high-speed%20nanocrystal-based%20photodiodes.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0183277%22%2C%22ISSN%22%3A%220003-6951%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0183277%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A16%3A03Z%22%7D%7D%2C%7B%22key%22%3A%22I7XD4KBX%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Chen%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EX.%20Chen%2C%20Z.-Q.%20Chen%2C%20L.%20Huang%2C%20C.%20Grebogi%2C%20Y.-C.%20Lai%2C%20Many-body%20spectral%20statistics%20of%20relativistic%20quantum%20billiard%20systems%2C%20Physical%20Review%20Research%205%20%282023%29%20013050.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevResearch.5.013050%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevResearch.5.013050%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Many-body%20spectral%20statistics%20of%20relativistic%20quantum%20billiard%20systems%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Xianzhang%22%2C%22lastName%22%3A%22Chen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Zhen-Qi%22%2C%22lastName%22%3A%22Chen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Liang%22%2C%22lastName%22%3A%22Huang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Celso%22%2C%22lastName%22%3A%22Grebogi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ying-Cheng%22%2C%22lastName%22%3A%22Lai%22%7D%5D%2C%22abstractNote%22%3A%22In%20the%20field%20of%20quantum%20chaos%2C%20spectral%20statistics%20is%20one%20of%20the%20most%20extensively%20investigated%20characteristics.%20Despite%20a%20large%20body%20of%20existing%20literature%2C%20the%20effects%20of%20many-body%20interactions%20on%20the%20spectral%20statistics%20of%20relativistic%20quantum%20systems%20remain%20poorly%20understood.%20Treating%20electron-electron%20interactions%20through%20the%20oneorbital%20mean-field%20Hubbard%20model%2C%20we%20address%20this%20fundamental%20issue%20using%20graphene%20billiards%20with%20the%20geometric%20shape%20of%20a%20circular%20sector%20as%20prototypical%20systems.%20Our%20approach%20is%20to%20consider%20the%20two%20characteristically%20different%20cases%20where%20the%20statistics%20are%20Poisson%20and%20Gaussian%20orthogonal%20ensemble%20%28GOE%29%20so%20the%20corresponding%20classical%20dynamics%20are%20typically%20integrable%20and%20chaotic%2C%20respectively%2C%20and%20to%20systematically%20investigate%20how%20the%20statistics%20change%20as%20the%20Hubbard%20interaction%20strength%20increases%20from%20zero.%20We%20find%20that%2C%20for%20energies%20near%20the%20Dirac%20point%2C%20the%20Hubbard%20interactions%20have%20a%20significant%20effect%20on%20the%20spectral%20statistics.%20Regardless%20of%20the%20type%20of%20spectral%20statistics%20to%20begin%20with%2C%20increasing%20the%20Hubbard%20interaction%20strength%20up%20to%20a%20critical%20value%20causes%20the%20statistics%20to%20approach%20GOE%2C%20rendering%20more%20applicable%20the%20random%20matrix%20theory.%20As%20the%20interaction%20strength%20increases%20beyond%20the%20critical%20value%2C%20the%20statistics%20evolve%20toward%20Poisson%2C%20due%20to%20the%20emergence%20of%20an%20energy%20gap%20rendering%20the%20quasiparticles%20massive.%20We%20also%20find%20that%20the%20energy%20levels%20above%20and%20below%20the%20Dirac%20point%20can%20exhibit%20different%20statistics%2C%20and%20the%20many-body%20interactions%20have%20little%20effect%20on%20the%20statistics%20for%20levels%20far%20from%20the%20Dirac%20point.%20These%20results%20reveal%20the%20intriguing%20interplay%20between%20many-body%20interactions%20and%20the%20spectral%20statistics%2C%20which%20we%20develop%20a%20physical%20picture%20to%20understand.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevResearch.5.013050%22%2C%22ISSN%22%3A%222643-1564%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1103%5C%2FPhysRevResearch.5.013050%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%5D%2C%22dateModified%22%3A%222023-05-31T13%3A23%3A08Z%22%7D%7D%2C%7B%22key%22%3A%22Y739VKV3%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Chen%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EX.%20Chen%2C%20G.%20Weick%2C%20D.%20Weinmann%2C%20R.A.%20Jalabert%2C%20Scanning%20gate%20microscopy%20in%20graphene%20nanostructures%2C%20Physical%20Review%20B%20107%20%282023%29%20085420.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.107.085420%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.107.085420%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Scanning%20gate%20microscopy%20in%20graphene%20nanostructures%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Xianzhang%22%2C%22lastName%22%3A%22Chen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guillaume%22%2C%22lastName%22%3A%22Weick%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Dietmar%22%2C%22lastName%22%3A%22Weinmann%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Rodolfo%20A.%22%2C%22lastName%22%3A%22Jalabert%22%7D%5D%2C%22abstractNote%22%3A%22The%20conductance%20of%20graphene%20nanoribbons%20and%20nanoconstrictions%20under%20the%20effect%20of%20a%20scanning%20gate%20mi-croscopy%20tip%20is%20systematically%20studied.%20Using%20a%20scattering%20approach%20for%20noninvasive%20probes%2C%20the%20first-and%20second-order%20conductance%20corrections%20caused%20by%20the%20tip%20potential%20disturbance%20are%20expressed%20explicitly%20in%20terms%20of%20the%20scattering%20states%20of%20the%20unperturbed%20structure.%20Numerical%20calculations%20confirm%20the%20perturbative%20results%2C%20showing%20that%20the%20second-order%20term%20prevails%20in%20the%20conductance%20plateaus%2C%20exhibiting%20a%20universal%20scaling%20law%20for%20armchair%20graphene%20strips.%20For%20stronger%20tips%2C%20at%20specific%20probe%20potential%20widths%20and%20strengths%20beyond%20the%20perturbative%20regime%2C%20the%20conductance%20corrections%20reveal%20the%20appearance%20of%20resonances%20originated%20from%20states%20trapped%20below%20the%20tip.%20The%20zero-transverse-energy%20mode%20of%20an%20armchair%20metallic%20strip%20is%20shown%20to%20be%20insensitive%20to%20the%20long-range%20electrostatic%20potential%20of%20the%20probe.%20For%20nanoconstrictions%20defined%20on%20a%20strip%2C%20scanning%20gate%20microscopy%20allows%20to%20get%20insight%20into%20the%20breakdown%20of%20conductance%20quantization.%20The%20first-order%20correction%20generically%20dominates%20at%20low%20tip%20strength%2C%20while%20for%20Fermi%20energies%20associated%20with%20faint%20conductance%20plateaus%2C%20the%20second-order%20correction%20becomes%20dominant%20for%20relatively%20small%20potential%20tip%20strengths.%20In%20accordance%20with%20the%20spatial%20dependence%20of%20the%20partial%20local%20density%20of%20states%2C%20the%20largest%20tip%20effect%20occurs%20in%20the%20central%20part%20of%20the%20constriction%2C%20close%20to%20the%20edges.%20Nanoribbons%20and%20nanoconstrictions%20with%20zigzag%20edges%20exhibit%20a%20similar%20response%20as%20in%20the%20case%20of%20armchair%20nanostructures%2C%20except%20when%20the%20intervalley%20coupling%20induced%20by%20the%20tip%20potential%20destroys%20the%20chiral%20edge%20states.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.107.085420%22%2C%22ISSN%22%3A%222469-9950%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1103%5C%2FPhysRevB.107.085420%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22EPW69HFA%22%5D%2C%22dateModified%22%3A%222024-09-10T14%3A57%3A35Z%22%7D%7D%2C%7B%22key%22%3A%22BN97B4QJ%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22d%27Aquino%20and%20Hertel%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20d%26%23x2019%3BAquino%2C%20R.%20Hertel%2C%20Micromagnetic%20frequency-domain%20simulation%20methods%20for%20magnonic%20systems%2C%20Journal%20of%20Applied%20Physics%20133%20%282023%29%20033902.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0131922%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0131922%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Micromagnetic%20frequency-domain%20simulation%20methods%20for%20magnonic%20systems%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Massimiliano%22%2C%22lastName%22%3A%22d%27Aquino%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Riccardo%22%2C%22lastName%22%3A%22Hertel%22%7D%5D%2C%22abstractNote%22%3A%22We%20present%20efficient%20numerical%20methods%20for%20the%20simulation%20of%20small%20magnetization%20oscillations%20in%20three-dimensional%20micromagnetic%20systems.%20Magnetization%20dynamics%20is%20described%20by%20the%20Landau-Lifshitz-Gilbert%20equation%2C%20linearized%20in%20the%20frequency%20domain%20around%20a%20generic%20equilibrium%20configuration%2C%20and%20formulated%20in%20a%20special%20operator%20form%20that%20allows%20leveraging%20large-scale%20techniques%20commonly%20used%20to%20evaluate%20the%20effective%20field%20in%20time-domain%20micromagnetic%20simulations.%20By%20using%20this%20formulation%2C%20we%20derive%20numerical%20algorithms%20to%20compute%20the%20free%20magnetization%20oscillations%20%28i.e.%2C%20spin%20wave%20eigenmodes%29%20as%20well%20as%20magnetization%20oscillations%20driven%20by%20ac%20radio-frequency%20fields%20for%20arbitrarily%20shaped%20nanomagnets.%20Moreover%2C%20semi-analytical%20perturbation%20techniques%20based%20on%20the%20computation%20of%20a%20reduced%20set%20of%20eigenmodes%20are%20provided%20for%20fast%20evaluation%20of%20magnetization%20frequency%20response%20and%20absorption%20spectra%20as%20a%20function%20of%20damping%20and%20ac%20field.%20We%20present%20both%20finite-difference%20and%20finite-element%20implementations%20and%20demonstrate%20their%20effectiveness%20on%20a%20test%20case.%20These%20techniques%20open%20the%20possibility%20to%20study%20generic%20magnonic%20systems%20discretized%20with%20several%20hundred%20thousands%20%28or%20even%20millions%29%20of%20computational%20cells%20in%20a%20reasonably%20short%20time.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0131922%22%2C%22ISSN%22%3A%220021-8979%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0131922%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A00%3A34Z%22%7D%7D%2C%7B%22key%22%3A%22HBF7H768%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22d%27Aquino%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20d%26%23x2019%3BAquino%2C%20S.%20Perna%2C%20M.%20Pancaldi%2C%20R.%20Hertel%2C%20S.%20Bonetti%2C%20C.%20Serpico%2C%20Micromagnetic%20study%20of%20inertial%20spin%20waves%20in%20ferromagnetic%20nanodots%2C%20Physical%20Review%20B%20107%20%282023%29%20144412.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.107.144412%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.107.144412%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Micromagnetic%20study%20of%20inertial%20spin%20waves%20in%20ferromagnetic%20nanodots%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Massimiliano%22%2C%22lastName%22%3A%22d%27Aquino%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Salvatore%22%2C%22lastName%22%3A%22Perna%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matteo%22%2C%22lastName%22%3A%22Pancaldi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Riccardo%22%2C%22lastName%22%3A%22Hertel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Stefano%22%2C%22lastName%22%3A%22Bonetti%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Claudio%22%2C%22lastName%22%3A%22Serpico%22%7D%5D%2C%22abstractNote%22%3A%22%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.107.144412%22%2C%22ISSN%22%3A%22%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Flink.aps.org%5C%2Fdoi%5C%2F10.1103%5C%2FPhysRevB.107.144412%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A00%3A40Z%22%7D%7D%2C%7B%22key%22%3A%22MZSC3ZED%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Desbuis%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EV.%20Desbuis%2C%20D.%20Lacour%2C%20C.%20Tiusan%2C%20W.%20Weber%2C%20M.%20Hehn%2C%20sp-%20and%20d-band%20effects%20on%20secondary%20low-energy%20electron%20generation%2C%20Physical%20Review%20B%20108%20%282023%29%20214424.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.214424%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.214424%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22sp-%20and%20d-band%20effects%20on%20secondary%20low-energy%20electron%20generation%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V.%22%2C%22lastName%22%3A%22Desbuis%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22D.%22%2C%22lastName%22%3A%22Lacour%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22C.%22%2C%22lastName%22%3A%22Tiusan%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Wolfgang%22%2C%22lastName%22%3A%22Weber%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Hehn%22%7D%5D%2C%22abstractNote%22%3A%22Ballistic%20hot%20electrons%20are%20extracted%20from%20a%20magnetic%20tunnel%20junction%20and%20injected%20into%20a%20metallic%20base%20with%20energies%20ranging%20from%200.65%20to%202.8%20eV.%20The%20energy%20and%20wave%20vector%20analysis%20made%20by%20a%20low%20height%20Si%5C%2FCu%20Schottky%20barrier%20allows%20one%20to%20disentangle%20the%20different%20contributions%20to%20the%20scattering.%20The%20hot%20electrons%20transport%20is%20interpreted%20as%20being%20mainly%20influenced%20by%20inelastic%20scattering.%20An%20explicit%20transport%20model%20reproduces%20our%20measurements%20and%20explains%20them%20as%20resulting%20directly%20from%20an%20electron-electron%20inelastic%20scattering%20process%20related%20to%20the%20sp%20and%20d%20bands%20of%20the%20ferromagnetic%20material%20involved.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.108.214424%22%2C%22ISSN%22%3A%222469-9950%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1103%5C%2FPhysRevB.108.214424%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22TR4ZUX8B%22%2C%22IUWT6S8X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A03%3A13Z%22%7D%7D%2C%7B%22key%22%3A%22Q5Q94VZ5%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Gadouche%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EF.Z.%20Gadouche%2C%20A.%20Kabir%2C%20S.%20Siouane%2C%20C.%20Sedrati%2C%20A.%20Bouabellou%2C%20G.%20Schmerber%2C%20Effect%20of%20the%20Substitution%20of%20Barium%20by%20Calcium%20on%20the%20Opto-Electronic%20Properties%20of%20Barium%20tin%20Oxide%2C%20Transactions%20on%20Electrical%20and%20Electronic%20Materials%20Early%20access%20%282023%29.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1007%5C%2Fs42341-023-00494-0%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1007%5C%2Fs42341-023-00494-0%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Effect%20of%20the%20Substitution%20of%20Barium%20by%20Calcium%20on%20the%20Opto-Electronic%20Properties%20of%20Barium%20tin%20Oxide%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22F.%20Z.%22%2C%22lastName%22%3A%22Gadouche%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22A.%22%2C%22lastName%22%3A%22Kabir%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22S.%22%2C%22lastName%22%3A%22Siouane%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22C.%22%2C%22lastName%22%3A%22Sedrati%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22A.%22%2C%22lastName%22%3A%22Bouabellou%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guy%22%2C%22lastName%22%3A%22Schmerber%22%7D%5D%2C%22abstractNote%22%3A%22The%20effect%20of%20the%20substitution%20of%20barium%20by%20calcium%20on%20structural%2C%20optical%20and%20luminescence%20properties%20of%20spray%20deposited%20barium%20tin%20oxide%20films%20was%20studied%20in%20this%20work%2C%20as%20a%20function%20of%20the%20calcium-based%20solution%20volume%20ratio%20RCa.%20According%20to%20X-ray%20diffraction%20%28XRD%29%20patterns%2C%20the%20substitution%20of%20barium%20by%20calcium%20induced%20an%20indirect%20phase%20transition%20from%20Ba3SnO%20to%20Ca3SnO.%20The%20Ba3Sn2O7%20metastable%20phase%20was%20identified%20for%20RCa%20%3D%200.3.%20The%20effect%20of%20the%20substitution%20of%20barium%20by%20calcium%20on%20optical%20properties%20was%20examined%20by%20UV-visible%20spectroscopy.%20As%20a%20function%20of%20RCa%2C%20the%20mean%20transmittance%2C%20in%20the%20visible%20domain%2C%20increased%20from%2050%20to%2080%25%20while%20the%20band%20gap%20energy%20decreased%20from%203.14%20to%203.09%20eV.%20PL%20spectra%20revealed%20that%20the%20substitution%20of%20barium%20by%20calcium%20increases%20the%20concentration%20of%20double%20ionized%20oxygen%20vacancies%20%28VO%2B%2B%29.%20The%20semiconducting%20behavior%20and%20the%20presence%20of%20defects%20made%20the%20deposited%20films%20promising%20materials%20for%20optoelectronics%2C%20gas%20sensing%20and%20photovoltaic%20conversion%20devices.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1007%5C%2Fs42341-023-00494-0%22%2C%22ISSN%22%3A%221229-7607%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1007%5C%2Fs42341-023-00494-0%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22ZN5EITAC%22%5D%2C%22dateModified%22%3A%222024-04-29T13%3A04%3A20Z%22%7D%7D%2C%7B%22key%22%3A%22S3EX8S8L%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Gumeniuk%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ER.%20Gumeniuk%2C%20V.%20Levytskyi%2C%20B.%20Kundys%2C%20A.%20Leithe-Jasper%2C%20Yb3Rh4Sn13%3A%20Two-gap%20superconductor%20with%20a%20complex%20Fermi%20surface%2C%20Physical%20Review%20B%20108%20%282023%29%20214515.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.214515%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.214515%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Yb3Rh4Sn13%3A%20Two-gap%20superconductor%20with%20a%20complex%20Fermi%20surface%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Roman%22%2C%22lastName%22%3A%22Gumeniuk%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Volodymyr%22%2C%22lastName%22%3A%22Levytskyi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Andreas%22%2C%22lastName%22%3A%22Leithe-Jasper%22%7D%5D%2C%22abstractNote%22%3A%22Structural%20and%20physical%20properties%20of%20the%20Yb3Rh4Sn13%20Remeika%20phase%20are%20investigated%20on%20large%20single%20crys-tals%20grown%20from%20Sn-flux.%20It%20crystallizes%20with%20disordered%20Y3Co4Ge13%20structure%20type%20%5Bspace%20group%20Pm3%20over%20bar%20n%2C%20a%20%3D%209.6709%282%29%20angstrom%5D%2C%20where%20the%2024k%20crystallographic%20site%20occupied%20by%20Sn%20atoms%20is%20split.%20Yb3Rh4Sn13%20is%20a%20superconductor%20%28SC%29%20with%20the%20critical%20temperature%20Tc%20%3D%207.63%285%29%20K%2C%20lower%20%5BBc1%20%3D%2014.5%285%29%20mT%5D%20and%20upper%20%5BBc2%280%29%20%3D%202.89%285%29%20T%5D%20critical%20fields%2C%20as%20well%20as%20a%20clear%20peak%20effect%20with%20B%2A%280%29%20%3D%201.96%289%29%20T%20observed%20in%20the%20M%28H%29%20loops.%20Bc2%28Tc%29%20can%20be%20described%20by%20the%20sum%20of%20two%20Werthamer-Helfand-Hohenberg%20equations.%20A%20gamma%28B%29%20proportional%20to%20B0.75%20dependency%20is%20found.%20The%20electronic%20specific%20heat%20below%20Tc%20follows%20an%20exponential%20function%20including%2087%25%20of%20a%20strongly%20coupled%20%5B%5Cu28031%5C%2FkBTc%20%3D%203.52%281%29%5D%20and%2013%25%20of%20a%20conventional%20s-wave-like%20%5B%5Cu28032%5C%2FkBTc%20%3D%201.32%281%29%5D%20gap.%20The%20observations%20are%20in%20line%20with%20Yb3Rh4Sn13%20being%20a%20two-gap%20SC.%20The%20Remeika%20phase%20reveals%20a%20complex%20electronic%20band%20structure%20studied%20by%20Hall%20coefficient%20%28RH%29%20measurements%20and%20calculations%20performed%20within%20the%20density%20functional%20theory.%20A%20%5C%22rattling%5C%22%20effect%20in%20Yb3Rh4Sn13%20is%20discussed%20based%20on%20structural%20refinements%20and%20phononic%20contributions%20to%20its%20specific%20heat%20capacity.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.108.214515%22%2C%22ISSN%22%3A%222469-9950%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1103%5C%2FPhysRevB.108.214515%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A16%3A18Z%22%7D%7D%2C%7B%22key%22%3A%222FKARSB9%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Hoeflich%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EK.%20Hoeflich%2C%20G.%20Hobler%2C%20F.I.%20Allen%2C%20T.%20Wirtz%2C%20G.%20Rius%2C%20L.%20McElwee-White%2C%20A.V.%20Krasheninnikov%2C%20M.%20Schmidt%2C%20I.%20Utke%2C%20N.%20Klingner%2C%20M.%20Osenberg%2C%20R.%20Cordoba%2C%20F.%20Djurabekova%2C%20I.%20Manke%2C%20P.%20Moll%2C%20M.%20Manoccio%2C%20J.M.%20De%20Teresa%2C%20L.%20Bischoff%2C%20J.%20Michler%2C%20O.%20De%20Castro%2C%20A.%20Delobbe%2C%20P.%20Dunne%2C%20O.V.%20Dobrovolskiy%2C%20N.%20Frese%2C%20A.%20Goelzhaeuser%2C%20P.%20Mazarov%2C%20D.%20Koelle%2C%20W.%20Moeller%2C%20F.%20Perez-Murano%2C%20P.%20Philipp%2C%20F.%20Vollnhals%2C%20G.%20Hlawacek%2C%20Roadmap%20for%20focused%20ion%20beam%20technologies%2C%20Applied%20Physics%20Reviews%2010%20%282023%29%20041311.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0162597%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0162597%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Roadmap%20for%20focused%20ion%20beam%20technologies%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Katja%22%2C%22lastName%22%3A%22Hoeflich%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gerhard%22%2C%22lastName%22%3A%22Hobler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Frances%20I.%22%2C%22lastName%22%3A%22Allen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tom%22%2C%22lastName%22%3A%22Wirtz%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gemma%22%2C%22lastName%22%3A%22Rius%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Lisa%22%2C%22lastName%22%3A%22McElwee-White%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Arkady%20V.%22%2C%22lastName%22%3A%22Krasheninnikov%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matthias%22%2C%22lastName%22%3A%22Schmidt%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ivo%22%2C%22lastName%22%3A%22Utke%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Nico%22%2C%22lastName%22%3A%22Klingner%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Markus%22%2C%22lastName%22%3A%22Osenberg%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Rosa%22%2C%22lastName%22%3A%22Cordoba%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Flyura%22%2C%22lastName%22%3A%22Djurabekova%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ingo%22%2C%22lastName%22%3A%22Manke%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Philip%22%2C%22lastName%22%3A%22Moll%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mariachiara%22%2C%22lastName%22%3A%22Manoccio%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jose%20Maria%22%2C%22lastName%22%3A%22De%20Teresa%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Lothar%22%2C%22lastName%22%3A%22Bischoff%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Johann%22%2C%22lastName%22%3A%22Michler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Olivier%22%2C%22lastName%22%3A%22De%20Castro%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anne%22%2C%22lastName%22%3A%22Delobbe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Peter%22%2C%22lastName%22%3A%22Dunne%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Oleksandr%20V.%22%2C%22lastName%22%3A%22Dobrovolskiy%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Natalie%22%2C%22lastName%22%3A%22Frese%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Armin%22%2C%22lastName%22%3A%22Goelzhaeuser%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Paul%22%2C%22lastName%22%3A%22Mazarov%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Dieter%22%2C%22lastName%22%3A%22Koelle%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Wolfhard%22%2C%22lastName%22%3A%22Moeller%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Francesc%22%2C%22lastName%22%3A%22Perez-Murano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Patrick%22%2C%22lastName%22%3A%22Philipp%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Florian%22%2C%22lastName%22%3A%22Vollnhals%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gregor%22%2C%22lastName%22%3A%22Hlawacek%22%7D%5D%2C%22abstractNote%22%3A%22The%20focused%20ion%20beam%20%28FIB%29%20is%20a%20powerful%20tool%20for%20fabrication%2C%20modification%2C%20and%20characterization%20of%20materials%20down%20to%20the%20nanoscale.%20Starting%20with%20the%20gallium%20FIB%2C%20which%20was%20originally%20intended%20for%20photomask%20repair%20in%20the%20semiconductor%20industry%2C%20there%20are%20now%20many%20different%20types%20of%20FIB%20that%20are%20commercially%20available.%20These%20instruments%20use%20a%20range%20of%20ion%20species%20and%20are%20applied%20broadly%20in%20materials%20science%2C%20physics%2C%20chemistry%2C%20biology%2C%20medicine%2C%20and%20even%20archaeology.%20The%20goal%20of%20this%20roadmap%20is%20to%20provide%20an%20overview%20of%20FIB%20instrumentation%2C%20theory%2C%20techniques%2C%20and%20applications.%20By%20viewing%20FIB%20developments%20through%20the%20lens%20of%20various%20research%20communities%2C%20we%20aim%20to%20identify%20future%20pathways%20for%20ion%20source%20and%20instrumentation%20development%2C%20as%20well%20as%20emerging%20applications%20and%20opportunities%20for%20improved%20understanding%20of%20the%20complex%20interplay%20of%20ion-solid%20interactions.%20We%20intend%20to%20provide%20a%20guide%20for%20all%20scientists%20in%20the%20field%20that%20identifies%20common%20research%20interest%20and%20will%20support%20future%20fruitful%20interactions%20connecting%20tool%20development%2C%20experiment%2C%20and%20theory.%20While%20a%20comprehensive%20overview%20of%20the%20field%20is%20sought%2C%20it%20is%20not%20possible%20to%20cover%20all%20research%20related%20to%20FIB%20technologies%20in%20detail.%20We%20give%20examples%20of%20specific%20projects%20within%20the%20broader%20context%2C%20referencing%20original%20works%20and%20previous%20review%20articles%20throughout.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0162597%22%2C%22ISSN%22%3A%221931-9401%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%5D%2C%22dateModified%22%3A%222024-04-29T13%3A04%3A39Z%22%7D%7D%2C%7B%22key%22%3A%22A8XI83QU%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Iurchuk%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EV.%20Iurchuk%2C%20J.%20Bran%2C%20M.%20Acosta%2C%20B.%20Kundys%2C%20A%20strain-controlled%20magnetostrictive%20pseudo%20spin%20valve%2C%20Applied%20Physics%20Letters%20122%20%282023%29%20072404.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0120426%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0120426%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22A%20strain-controlled%20magnetostrictive%20pseudo%20spin%20valve%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Vadym%22%2C%22lastName%22%3A%22Iurchuk%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Julien%22%2C%22lastName%22%3A%22Bran%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Manuel%22%2C%22lastName%22%3A%22Acosta%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%5D%2C%22abstractNote%22%3A%22Electric-field%20control%20of%20magnetism%20via%20an%20inverse%20magnetostrictive%20effect%20is%20an%20alternative%20path%20toward%20improving%20energy-efficient%20storage%20and%20sensing%20devices%20based%20on%20a%20giant%20magnetoresistance%20effect.%20In%20this%20Letter%2C%20we%20report%20on%20lateral%20electric-field%20driven%20strain-mediated%20modulation%20of%20magnetotransport%20properties%20in%20a%20Co%5C%2FCu%5C%2FPy%20pseudo%20spin%20valve%20grown%20on%20a%20ferroelectric%200.7Pb%5BMg1%5C%2F3Nb2%5C%2F3%29%5DO-3-0.3PbTiO%283%29%20substrate.%20We%20show%20a%20decrease%20in%20the%20giant%20magnetoresistance%20ratio%20of%20the%20pseudo%20spin%20valve%20with%20the%20increase%20in%20the%20electric%20field%2C%20which%20is%20attributed%20to%20the%20deviation%20of%20the%20Co%20layer%20magnetization%20from%20the%20initial%20direction%20due%20to%20strain-induced%20magnetoelastic%20anisotropy%20contribution.%20Additionally%2C%20we%20demonstrate%20that%20strain-induced%20magnetic%20anisotropy%20effectively%20shifts%20the%20switching%20field%20of%20the%20magnetostrictive%20Co%20layer%2C%20while%20keeping%20the%20switching%20field%20of%20the%20nearly%20zero-magnetostrictive%20Py%20layer%20unaffected%20due%20to%20its%20negligible%20magnetostriction.%20We%20argue%20that%20magnetostrictively%20optimized%20magnetic%20films%20in%20properly%20engineered%20multilayered%20structures%20can%20offer%20a%20path%20to%20enhancing%20the%20selective%20magnetic%20switching%20in%20spintronic%20devices.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0120426%22%2C%22ISSN%22%3A%220003-6951%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0120426%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22EAI2UDK5%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A16%3A29Z%22%7D%7D%2C%7B%22key%22%3A%22L73GSYPE%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Kapustianyk%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EV.%20Kapustianyk%2C%20U.%20Mostovoi%2C%20S.%20Semak%2C%20Y.%20Eliyashevskyy%2C%20Effects%20of%20Annealing%20and%20Domain%20Structure%20on%20the%20Photovoltaic%20Response%20in%20Pb%5B%28Mg1%5C%2F3Nb2%5C%2F3%290.70Ti0.30%5DO3%20Single%20Crystal%2C%20Physica%20Status%20Solidi%20B-Basic%20Solid%20State%20Physics%20early%20access%20%282023%29%202300372.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1002%5C%2Fpssb.202300372%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1002%5C%2Fpssb.202300372%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Effects%20of%20Annealing%20and%20Domain%20Structure%20on%20the%20Photovoltaic%20Response%20in%20Pb%5B%28Mg1%5C%2F3Nb2%5C%2F3%290.70Ti0.30%5DO3%20Single%20Crystal%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Volodymyr%22%2C%22lastName%22%3A%22Kapustianyk%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ustym%22%2C%22lastName%22%3A%22Mostovoi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Svitlana%22%2C%22lastName%22%3A%22Semak%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yuriy%22%2C%22lastName%22%3A%22Eliyashevskyy%22%7D%5D%2C%22abstractNote%22%3A%22Crystalline%20acentricity%20leading%20to%20the%20photovoltaic%20%28PV%29%20effect%20in%20ferroelectrics%20%28FEs%29%20emerges%20these%20materials%20as%20important%20candidates%20for%20the%20PV%20cells%20potentially%20overcoming%20the%20Shockley-Queisser%20limit%20of%20semiconductors.%20However%2C%20this%20research%20direction%20still%20requires%20more%20investigations%20to%20develop%20reliable%20pathways%20for%20PV%20efficiency%20optimization.%20Herein%2C%20it%20is%20reported%20that%20due%20to%20the%20sample%20annealing%20above%20the%20Curie%20point%20the%20PV%20effect%20asymmetry%20with%20respect%20to%20the%20poling%20sign%20can%20be%20compensated%20and%20intrinsic%20PV%20response%20of%20the%20FE%20crystal%20can%20be%20increased%20by%20more%20than%2020%25%20in%20comparison%20with%20the%20pristine%20sample.%20It%20is%20also%20reported%20how%20the%20orientation%20of%20domain%20walls%20can%20be%20used%20to%20engineer%20the%20PV%20effect%20in%20the%20subcoercive%20electric%20field%20region.%20The%20reported%20results%20contribute%20to%20better%20understanding%20of%20PV%20effect%20tuning%20in%20the%20FEs%20paving%20the%20way%20for%20more%20efficient%20and%20sustainable%20solar%20energy%20utilization.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1002%5C%2Fpssb.202300372%22%2C%22ISSN%22%3A%220370-1972%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1002%5C%2Fpssb.202300372%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%5D%2C%22dateModified%22%3A%222024-04-29T13%3A04%3A48Z%22%7D%7D%2C%7B%22key%22%3A%22WTQE6MYV%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Kremer%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EG.%20Kremer%2C%20A.%20Mahmoudi%2C%20A.%20M%26%23x2019%3BFoukh%2C%20M.%20Bouaziz%2C%20M.%20Rahimi%2C%20M.L.%20Della%20Rocca%2C%20P.%20Le%20Fevre%2C%20J.-F.%20Dayen%2C%20F.%20Bertran%2C%20S.%20Matzen%2C%20M.%20Pala%2C%20J.%20Chaste%2C%20F.%20Oehler%2C%20A.%20Ouerghi%2C%20Quantum%20Confinement%20and%20Electronic%20Structure%20at%20the%20Surface%20of%20van%20der%20Waals%20Ferroelectric%20%26amp%3B%20alpha%3B%20-In2Se3%2C%20ACS%20Nano%2017%20%282023%29%2018924%26%23x2013%3B18931.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsnano.3c04186%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsnano.3c04186%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Quantum%20Confinement%20and%20Electronic%20Structure%20at%20the%20Surface%20of%20van%20der%20Waals%20Ferroelectric%20%26%20alpha%3B%20-In2Se3%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Geoffroy%22%2C%22lastName%22%3A%22Kremer%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Aymen%22%2C%22lastName%22%3A%22Mahmoudi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Adel%22%2C%22lastName%22%3A%22M%27Foukh%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Meryem%22%2C%22lastName%22%3A%22Bouaziz%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mehrdad%22%2C%22lastName%22%3A%22Rahimi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Maria%20Luisa%22%2C%22lastName%22%3A%22Della%20Rocca%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Patrick%22%2C%22lastName%22%3A%22Le%20Fevre%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Francois%22%2C%22lastName%22%3A%22Bertran%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sylvia%22%2C%22lastName%22%3A%22Matzen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Marco%22%2C%22lastName%22%3A%22Pala%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Julien%22%2C%22lastName%22%3A%22Chaste%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Fabrice%22%2C%22lastName%22%3A%22Oehler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Abdelkarim%22%2C%22lastName%22%3A%22Ouerghi%22%7D%5D%2C%22abstractNote%22%3A%22Two-dimensional%20%282D%29%20ferroelectric%20%28FE%29%20materials%20arepromisingcompounds%20for%20next-generation%20nonvolatile%20memories%20due%20to%20their%20lowenergy%20consumption%20and%20high%20endurance.%20Among%20them%2C%20%26%20alpha%3B-In2Se3%20has%20drawn%20particular%20attention%20due%20to%20its%20in-and%20out-of-plane%20ferroelectricity%2C%20whose%20robustness%20has%20been%20demonstrateddown%20to%20the%20monolayer%20limit.%20This%20is%20a%20relatively%20uncommon%20behaviorsince%20most%20bulk%20FE%20materials%20lose%20their%20ferroelectric%20character%20atthe%202D%20limit%20due%20to%20the%20depolarization%20field.%20Using%20angle%20resolvedphotoemission%20spectroscopy%20%28ARPES%29%2C%20we%20unveil%20another%20unusual%202D%20phenomenonappearing%20in%202H%20%26%20alpha%3B-In2Se3%20single%20crystals%2Cthe%20occurrence%20of%20a%20highly%20metallic%20two-dimensional%20electron%20gas%20%282DEG%29at%20the%20surface%20of%20vacuum-cleaved%20crystals.%20This%202DEG%20exhibits%20twoconfined%20states%2C%20which%20correspond%20to%20an%20electron%20density%20of%20approximately10%2813%29%20electrons%5C%2Fcm%282%29%2C%20also%20confirmed%20by%20thermoelectricmeasurements.%20Combination%20of%20ARPES%20and%20density%20functional%20theory%20%28DFT%29calculations%20reveals%20a%20direct%20band%20gap%20of%20energy%20equal%20to%201.3%20%26%20PLUSMN%3B0.1%20eV%2C%20with%20the%20bottom%20of%20the%20conduction%20band%20localized%20at%20the%20centerof%20the%20Brillouin%20zone%2C%20just%20below%20the%20Fermi%20level.%20Such%20strong%20n-typedoping%20further%20supports%20the%20quantum%20confinement%20of%20electrons%20and%20theformation%20of%20the%202DEG.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1021%5C%2Facsnano.3c04186%22%2C%22ISSN%22%3A%221936-0851%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1021%5C%2Facsnano.3c04186%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A16%3A48Z%22%7D%7D%2C%7B%22key%22%3A%22Q2C9Y5DL%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Kurian%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EJ.%20Kurian%2C%20A.%20Joseph%2C%20S.%20Cherifi-Hertel%2C%20C.%20Fowley%2C%20G.%20Hlawacek%2C%20P.%20Dunne%2C%20M.%20Romeo%2C%20G.%20Atcheson%2C%20J.M.D.%20Coey%2C%20B.%20Doudin%2C%20Deterministic%20multi-level%20spin%20orbit%20torque%20switching%20using%20focused%20He%2B%20ion%20beam%20irradiation%2C%20Applied%20Physics%20Letters%20122%20%282023%29%20032402.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0131188%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0131188%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Deterministic%20multi-level%20spin%20orbit%20torque%20switching%20using%20focused%20He%2B%20ion%20beam%20irradiation%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jinu%22%2C%22lastName%22%3A%22Kurian%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Aleena%22%2C%22lastName%22%3A%22Joseph%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Salia%22%2C%22lastName%22%3A%22Cherifi-Hertel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ciaran%22%2C%22lastName%22%3A%22Fowley%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gregor%22%2C%22lastName%22%3A%22Hlawacek%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Peter%22%2C%22lastName%22%3A%22Dunne%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Michelangelo%22%2C%22lastName%22%3A%22Romeo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gwenael%22%2C%22lastName%22%3A%22Atcheson%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22J.%20M.%20D.%22%2C%22lastName%22%3A%22Coey%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bernard%22%2C%22lastName%22%3A%22Doudin%22%7D%5D%2C%22abstractNote%22%3A%22He%2B%20ion%20irradiation%20is%20used%20to%20pattern%20multiple%20areas%20of%20Pt%5C%2FCo%5C%2FW%20films%20with%20different%20irradiation%20doses%20in%20Hall%20bars.%20The%20resulting%20perpendicular%20magnetic%20anisotropy%20landscape%20enables%20selective%20multilevel%20current-induced%20switching%20with%20full%20deterministic%20control%20of%20the%20position%20and%20order%20of%20the%20individual%20switching%20elements.%20Key%20pattern%20design%20parameters%20are%20specified%2C%20opening%20a%20way%20to%20scalable%20multi-level%20switching%20devices.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0131188%22%2C%22ISSN%22%3A%220003-6951%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0131188%22%2C%22collections%22%3A%5B%22DEB5KWFS%22%2C%22MKAFAH44%22%2C%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A16%3A53Z%22%7D%7D%2C%7B%22key%22%3A%22BAML9KFG%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Leumer%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EN.G.%20Leumer%2C%20On%20symmetric%20Tetranacci%20polynomials%20in%20mathematics%20and%20physics%2C%20Journal%20of%20Physics%20A-Mathematical%20and%20Theoretical%2056%20%282023%29%20435202.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1088%5C%2F1751-8121%5C%2Facfbcd%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1088%5C%2F1751-8121%5C%2Facfbcd%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22On%20symmetric%20Tetranacci%20polynomials%20in%20mathematics%20and%20physics%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Nico%20G.%22%2C%22lastName%22%3A%22Leumer%22%7D%5D%2C%22abstractNote%22%3A%22In%20this%20manuscript%2C%20we%20introduce%20%28symmetric%29%20Tetranacci%20polynomials%20xi%20j%20as%20a%20twofold%20generalization%20of%20ordinary%20Tetranacci%20numbers%2C%20considering%20both%20non%20unity%20coefficients%20and%20generic%20initial%20values.%20We%20derive%20a%20complete%20closed%20form%20expression%20for%20any%20xi%20j%20with%20the%20key%20feature%20of%20a%20decomposition%20in%20terms%20of%20generalized%20Fibonacci%20polynomials.%20For%20suitable%20conditions%2C%20xi%20j%20can%20be%20understood%20as%20the%20superposition%20of%20standing%20waves.%20The%20issue%20of%20Tetranacci%20polynomials%20originated%20from%20their%20application%20in%20condensed%20matter%20physics.%20We%20explicitly%20demonstrate%20the%20approach%20for%20the%20spectrum%2C%20eigenvectors%2C%20Green%27s%20functions%20and%20transmission%20probability%20for%20an%20atomic%20tight%20binding%20chain%20exhibiting%20both%20nearest%20and%20next%20nearest%20neighbor%20processes.%20We%20demonstrate%20that%20in%20topological%20trivial%20models%2C%20complex%20wavevectors%20can%20form%20bulk%20states%20as%20a%20result%20of%20the%20open%20boundary%20conditions.%20We%20describe%20how%20effective%20next%20nearest%20neighbor%20bonding%20is%20engineered%20in%20state%20of%20the%20art%20theory%5C%2Fexperiment%20exploiting%20onsite%20degrees%20of%20freedom%20and%20close%20range%20hopping.%20We%20argue%20about%20experimental%20tune%20ability%20and%20on-demand%20complex%20wavevectors.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1088%5C%2F1751-8121%5C%2Facfbcd%22%2C%22ISSN%22%3A%221751-8113%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1088%5C%2F1751-8121%5C%2Facfbcd%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22EPW69HFA%22%5D%2C%22dateModified%22%3A%222024-09-18T11%3A54%3A03Z%22%7D%7D%2C%7B%22key%22%3A%22UAHGENQS%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Lopez%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EL.E.P.%20Lopez%2C%20A.%20Roslawska%2C%20F.%20Scheurer%2C%20S.%20Berciaud%2C%20G.%20Schull%2C%20Tip-induced%20excitonic%20luminescence%20nanoscopy%20of%20an%20atomically%20resolved%20van%20der%20Waals%20heterostructure.%2C%20Nature%20Materials%2022%20%282023%29%20482%26%23x2013%3B488.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41563-023-01494-4%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41563-023-01494-4%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Tip-induced%20excitonic%20luminescence%20nanoscopy%20of%20an%20atomically%20resolved%20van%20der%20Waals%20heterostructure.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Luis%20E%20Parra%22%2C%22lastName%22%3A%22Lopez%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anna%22%2C%22lastName%22%3A%22Roslawska%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Fabrice%22%2C%22lastName%22%3A%22Scheurer%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Stephane%22%2C%22lastName%22%3A%22Berciaud%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guillaume%22%2C%22lastName%22%3A%22Schull%22%7D%5D%2C%22abstractNote%22%3A%22The%20electronic%20and%20optical%20properties%20of%20van%20der%20Waals%20heterostructures%20are%20strongly%20influenced%20by%20the%20structuration%20and%20homogeneity%20of%20their%20nano-%20and%20atomic-scale%20environments.%20Unravelling%20this%20intimate%20structure-property%20relationship%20is%20a%20key%20challenge%20that%20requires%20methods%20capable%20of%20addressing%20the%20light-matter%20interactions%20in%20van%20der%20Waals%20materials%20with%20ultimate%20spatial%20resolution.%20Here%20we%20use%20a%20low-temperature%20scanning%20tunnelling%20microscope%20to%20probe-with%20atomic-scale%20resolution-the%20excitonic%20luminescence%20of%20a%20van%20der%20Waals%20heterostructure%2C%20made%20of%20a%20transition%20metal%20dichalcogenide%20monolayer%20stacked%20onto%20a%20few-layer%20graphene%20flake%20supported%20by%20a%20Au%28111%29%20substrate.%20Sharp%20emission%20lines%20arising%20from%20neutral%2C%20charged%20and%20localized%20excitons%20are%20reported.%20Their%20intensities%20and%20emission%20energies%20vary%20as%20a%20function%20of%20the%20nanoscale%20topography%20of%20the%20van%20der%20Waals%20heterostructure%2C%20explaining%20the%20variability%20of%20the%20emission%20properties%20observed%20with%20diffraction-limited%20approaches.%20Our%20work%20paves%20the%20way%20towards%20understanding%20and%20controlling%20optoelectronic%20phenomena%20in%20moire%20superlattices%20with%20atomic-scale%20resolution.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1038%5C%2Fs41563-023-01494-4%22%2C%22ISSN%22%3A%221476-4660%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1038%5C%2Fs41563-023-01494-4%22%2C%22collections%22%3A%5B%229USMFXMV%22%2C%22DEB5KWFS%22%2C%22UVN4N32C%22%2C%22J4NL8E8U%22%5D%2C%22dateModified%22%3A%222024-09-10T14%3A48%3A13Z%22%7D%7D%2C%7B%22key%22%3A%226TMF9L8C%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Magnifouet%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EG.%20Magnifouet%2C%20M.%20Vallet%2C%20E.%20Meslin%2C%20M.%20Walls%2C%20C.%20Bouillet%2C%20J.%20Arabski%2C%20V.%20Pierron-Bohnes%2C%20Strains%20in%20Fe%5C%2FCr%5C%2FFe%20trilayers%20and%20%28Fe%5C%2FCr%295%5C%2FFe%20multilayers%20epitaxied%20on%20MgO%20and%20MgO%5C%2FSrTiO3%2C%20Thin%20Solid%20Films%20780%20%282023%29%20139949.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2Fhttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.tsf.2023.139949%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2Fhttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.tsf.2023.139949%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Strains%20in%20Fe%5C%2FCr%5C%2FFe%20trilayers%20and%20%28Fe%5C%2FCr%295%5C%2FFe%20multilayers%20epitaxied%20on%20MgO%20and%20MgO%5C%2FSrTiO3%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gladys%22%2C%22lastName%22%3A%22Magnifouet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Vallet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22E.%22%2C%22lastName%22%3A%22Meslin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Walls%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Corinne%22%2C%22lastName%22%3A%22Bouillet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jacek%22%2C%22lastName%22%3A%22Arabski%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V%5Cu00e9ronique%22%2C%22lastName%22%3A%22Pierron-Bohnes%22%7D%5D%2C%22abstractNote%22%3A%22Fe%5C%2FCr%5C%2FFe%20trilayers%20and%20multilayers%20are%20prepared%20as%20model%20systems%20designed%20to%20furnish%20simple%20data%20comparable%20with%20calculation%20results%20for%20diffusion%20properties%20in%20nuclear%20materials.%20Their%20structure%20%28epitaxy%2C%20residual%20strains%20and%20dislocations%29%20is%20characterized%20in%20detail.%20The%20film%20structure%20%28strain%20and%20stress%29%20is%20shown%20to%20be%20different%20on%20MgO20nm%5C%2FSrTiO3%20and%20MgO%20substrates%20due%20to%20the%20residual%20strain%20in%20the%20MgO%20buffer%20layer%20on%20SrTiO3.%20Superlattices%20with%20high%20crystalline%20quality%20are%20prepared%2C%20with%20Fe%20and%20Cr%20in%20coherent%20epitaxy.%20In-plane%20residual%20strain%20in%20Fe%20is%20%2B0.45%2813%29%25%20on%20MgO%20substrates%20and%20decreases%20from%201.70%289%29%25%20to%200.47%282%29%25%20when%20increasing%20the%20thickness%20of%20the%20trilayers%20on%20MgO%5C%2FSrTiO3%20substrates.%20These%20strains%20enhance%20the%20contrast%20between%20Fe%20and%20Cr%2C%20opening%20the%20way%20to%20future%20kinetics%20studies%20using%20x-ray%20diffraction%20in%20this%20system%2C%20which%20is%20far%20more%20efficient%20%28non-destructive%20and%20rapid%29%20than%20high%20resolution%20transmission%20electron%20microscopy%20with%20electron%20energy%20loss%20spectroscopy%20or%20atom%20probe%20tomography.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%22https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.tsf.2023.139949%22%2C%22ISSN%22%3A%220040-6090%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fwww.sciencedirect.com%5C%2Fscience%5C%2Farticle%5C%2Fpii%5C%2FS0040609023002791%22%2C%22collections%22%3A%5B%22DEB5KWFS%22%2C%22UVN4N32C%22%2C%22WJDNKBGA%22%2C%22ZN5EITAC%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A00%3A46Z%22%7D%7D%2C%7B%22key%22%3A%22SAR4V2VQ%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Maity%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EK.%20Maity%2C%20J.-F.%20Dayen%2C%20B.%20Doudin%2C%20R.%20Gumeniuk%2C%20B.%20Kundys%2C%20Single%20Wavelength%20Operating%20Neuromorphic%20Device%20Based%20on%20a%20Graphene-Ferroelectric%20Transistor.%2C%20ACS%20Applied%20Materials%20%26amp%3B%20Interfaces%2015%20%282023%29%2055948%26%23x2013%3B55956.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsami.3c10010%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsami.3c10010%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Single%20Wavelength%20Operating%20Neuromorphic%20Device%20Based%20on%20a%20Graphene-Ferroelectric%20Transistor.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Krishna%22%2C%22lastName%22%3A%22Maity%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bernard%22%2C%22lastName%22%3A%22Doudin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Roman%22%2C%22lastName%22%3A%22Gumeniuk%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%5D%2C%22abstractNote%22%3A%22As%20global%20data%20generation%20continues%20to%20rise%2C%20there%20is%20an%20increasing%20demand%20for%20revolutionary%20in-memory%20computing%20methodologies%20and%20efficient%20machine%20learning%20solutions.%20Despite%20recent%20progress%20in%20electrical%20and%20electro-optical%20simulations%20of%20machine%20learning%20devices%2C%20the%20all-optical%20nonthermal%20function%20remains%20challenging%2C%20with%20single%20wavelength%20operation%20still%20elusive.%20Here%20we%20report%20on%20an%20optical%20and%20monochromatic%20way%20of%20neuromorphic%20signal%20processing%20for%20brain-inspired%20functions%2C%20eliminating%20the%20need%20for%20electrical%20pulses.%20Multilevel%20synaptic%20potentiation-depression%20cycles%20are%20successfully%20achieved%20optically%20by%20leveraging%20photovoltaic%20charge%20generation%20and%20polarization%20within%20the%20photoferroelectric%20substrate%20interfaced%20with%20the%20graphene%20sensor.%20Furthermore%2C%20the%20demonstrated%20low-power%20prototype%20device%20is%20able%20to%20reproduce%20exact%20signal%20profile%20of%20brain%20tissues%20yet%20with%20more%20than%202%20orders%20of%20magnitude%20faster%20response.%20The%20reported%20properties%20should%20trigger%20all-optical%20and%20low%20power%20artificial%20neuromorphic%20development%20based%20on%20photoferroelectric%20structures.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1021%5C%2Facsami.3c10010%22%2C%22ISSN%22%3A%221944-8252%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1021%5C%2Facsami.3c10010%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A17%3A04Z%22%7D%7D%2C%7B%22key%22%3A%22PPLPUDP4%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Maity%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EK.%20Maity%2C%20J.-F.%20Dayen%2C%20M.%20Palluel%2C%20N.%20Daro%2C%20G.%20Chastanet%2C%20B.%20Kundys%2C%20B.%20Doudin%2C%20Elucidating%20the%20effect%20of%20spin%20crossover%20materials%20on%20graphene%20sensing%20devices%2C%20Applied%20Physics%20Letters%20123%20%282023%29%20163503.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0163784%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0163784%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Elucidating%20the%20effect%20of%20spin%20crossover%20materials%20on%20graphene%20sensing%20devices%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Krishna%22%2C%22lastName%22%3A%22Maity%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Marlene%22%2C%22lastName%22%3A%22Palluel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Nathalie%22%2C%22lastName%22%3A%22Daro%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guillaume%22%2C%22lastName%22%3A%22Chastanet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bernard%22%2C%22lastName%22%3A%22Doudin%22%7D%5D%2C%22abstractNote%22%3A%22Graphene%20films%20are%20used%20to%20detect%20the%20presence%20and%20transition%20of%20spin%20crossover%20nanoparticle%20aggregates.%20Experiments%20performed%20far%20from%20the%20graphene%20neutrality%20point%2C%20combining%20impedance%20spectroscopy%20and%20Hall%20measurements%2C%20provide%20better%20insight%20into%20the%20mechanism%20for%20the%20change%20of%20impedance%20of%20the%20graphene%20layer%20in%20proximity%20with%20different%20states%20of%20the%20molecular%20structure.%20We%20observe%20that%20the%20change%20of%20spin%20state%20shifts%20the%20graphene%20Fermi%20level%20and%20its%20intrinsic%20resistance%2C%20with%20resulting%20positive%20insight%20into%20using%20this%20type%20of%20hybrid%20device%20for%20fast%20molecular%20electronics%20purposes.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0163784%22%2C%22ISSN%22%3A%220003-6951%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0163784%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A17%3A16Z%22%7D%7D%2C%7B%22key%22%3A%22XNSXW6WL%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Mark%5Cu00f3%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ED.%20Mark%26%23xF3%3B%2C%20R.%20Cheenikundil%2C%20J.%20Bauer%2C%20K.%20Lenz%2C%20W.-C.%20Chuang%2C%20K.-W.%20Lin%2C%20J.-C.%20Wu%2C%20M.%20d%26%23x2019%3BAquino%2C%20R.%20Hertel%2C%20D.S.%20Schmool%2C%20Interpretation%20of%20Spin-Wave%20Modes%20in%20%5C%5CmathrmCo%5C%2F%5C%5CmathrmAg%20Nanodot%20Arrays%20Probed%20by%20Broadband%20Ferromagnetic%20Resonance%2C%20Physical%20Review%20Applied%2020%20%282023%29%20024059.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevApplied.20.024059%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevApplied.20.024059%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Interpretation%20of%20Spin-Wave%20Modes%20in%20%5C%5CmathrmCo%5C%2F%5C%5CmathrmAg%20Nanodot%20Arrays%20Probed%20by%20Broadband%20Ferromagnetic%20Resonance%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Daniel%22%2C%22lastName%22%3A%22Mark%5Cu00f3%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Rajgowrav%22%2C%22lastName%22%3A%22Cheenikundil%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Julien%22%2C%22lastName%22%3A%22Bauer%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Kilian%22%2C%22lastName%22%3A%22Lenz%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Wan-Chen%22%2C%22lastName%22%3A%22Chuang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ko-Wei%22%2C%22lastName%22%3A%22Lin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jong-Ching%22%2C%22lastName%22%3A%22Wu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Massimiliano%22%2C%22lastName%22%3A%22d%27Aquino%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Riccardo%22%2C%22lastName%22%3A%22Hertel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22David%20S.%22%2C%22lastName%22%3A%22Schmool%22%7D%5D%2C%22abstractNote%22%3A%22%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevApplied.20.024059%22%2C%22ISSN%22%3A%22%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Flink.aps.org%5C%2Fdoi%5C%2F10.1103%5C%2FPhysRevApplied.20.024059%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A00%3A51Z%22%7D%7D%2C%7B%22key%22%3A%22XNT4E52M%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Oukaci%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EK.A.%20Oukaci%2C%20D.%20Stoeffler%2C%20M.%20Hehn%2C%20M.%20Grassi%2C%20B.%20Sarpi%2C%20M.%20Bailleul%2C%20Y.%20Henry%2C%20S.%20Petit%2C%20F.%20Montaigne%2C%20R.%20Belkhou%2C%20D.%20Lacour%2C%20Oscillatory%20buckling%20reversal%20of%20a%20weak%20stripe%20magnetic%20texture%2C%20Materials%20Research%20Letters%2011%20%282023%29%20789%26%23x2013%3B795.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1080%5C%2F21663831.2023.2238010%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1080%5C%2F21663831.2023.2238010%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Oscillatory%20buckling%20reversal%20of%20a%20weak%20stripe%20magnetic%20texture%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22K.%20Ait%22%2C%22lastName%22%3A%22Oukaci%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Daniel%22%2C%22lastName%22%3A%22Stoeffler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Hehn%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Grassi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22B.%22%2C%22lastName%22%3A%22Sarpi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mathieu%22%2C%22lastName%22%3A%22Bailleul%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yves%22%2C%22lastName%22%3A%22Henry%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22S.%22%2C%22lastName%22%3A%22Petit%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22F.%22%2C%22lastName%22%3A%22Montaigne%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22R.%22%2C%22lastName%22%3A%22Belkhou%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22D.%22%2C%22lastName%22%3A%22Lacour%22%7D%5D%2C%22abstractNote%22%3A%22%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1080%5C%2F21663831.2023.2238010%22%2C%22ISSN%22%3A%22null%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1080%5C%2F21663831.2023.2238010%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A00%3A57Z%22%7D%7D%2C%7B%22key%22%3A%22VCAZHGXD%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Pandey%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ES.%20Pandey%2C%20S.%20Hettler%2C%20R.%20Arenal%2C%20C.%20Bouillet%2C%20A.R.%20Moghe%2C%20S.%20Berciaud%2C%20J.%20Robert%2C%20J.-F.%20Dayen%2C%20D.%20Halley%2C%20Room-temperature%20anomalous%20Hall%20effect%20in%20graphene%20in%20interfacial%20magnetic%20proximity%20to%20EuO%20grown%20by%20topotactic%20reduction%2C%20Physical%20Review%20B%20108%20%282023%29%20144423.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.144423%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.144423%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Room-temperature%20anomalous%20Hall%20effect%20in%20graphene%20in%20interfacial%20magnetic%20proximity%20to%20EuO%20grown%20by%20topotactic%20reduction%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Satakshi%22%2C%22lastName%22%3A%22Pandey%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Simon%22%2C%22lastName%22%3A%22Hettler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Raul%22%2C%22lastName%22%3A%22Arenal%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Corinne%22%2C%22lastName%22%3A%22Bouillet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Aditi%20Raman%22%2C%22lastName%22%3A%22Moghe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Stephane%22%2C%22lastName%22%3A%22Berciaud%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jerome%22%2C%22lastName%22%3A%22Robert%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22David%22%2C%22lastName%22%3A%22Halley%22%7D%5D%2C%22abstractNote%22%3A%22We%20show%20that%20thin%20layers%20of%20EuO%2C%20a%20ferromagnetic%20insulator%2C%20can%20be%20achieved%20by%20topotactic%20reduction%20under%20titanium%20of%20a%20Eu2O3%20film%20deposited%20on%20top%20of%20a%20graphene%20template.%20The%20reduction%20process%20leads%20to%20the%20formation%20of%20a%207-nm-thick%20EuO%20smooth%20layer%2C%20without%20noticeable%20structural%20changes%20in%20the%20underlying%20chemical%20vapor%20deposited%20graphene.%20The%20obtained%20EuO%20films%20exhibit%20ferromagnetism%2C%20with%20a%20Curie%20temperature%20that%20decreases%20with%20the%20initially%20deposited%20Eu2O3%20layer%20thickness.%20By%20adjusting%20the%20thickness%20of%20the%20Eu2O3%20layer%20below%207%20nm%2C%20we%20promote%20the%20formation%20of%20EuO%20at%20the%20very%20graphene%20interface%3A%20the%20EuO%5C%2Fgraphene%20heterostructure%20demonstrates%20the%20anomalous%20Hall%20effect%20%28AHE%29%2C%20which%20is%20a%20fingerprint%20of%20proximity-induced%20spin%20polarization%20in%20graphene.%20The%20AHE%20signal%20moreover%20persists%20above%20Tc%20up%20to%20350%20K%20due%20to%20a%20robust%20super-paramagnetic%20phase%20in%20EuO.%20This%20original%20high-temperature%20magnetic%20phase%20is%20attributed%20to%20magnetic%20polarons%20in%20EuO%3A%20we%20propose%20that%20the%20high%20strain%20in%20our%20EuO%20films%20grown%20on%20graphene%20stabilizes%20the%20magnetic%20polarons%20up%20to%20room%20temperature.%20This%20effect%20is%20different%20from%20the%20case%20of%20bulk%20EuO%20in%20which%20polarons%20vanish%20in%20the%20vicinity%20of%20the%20Curie%20temperature%20T-c%20%3D%2069%20K.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.108.144423%22%2C%22ISSN%22%3A%222469-9950%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1103%5C%2FPhysRevB.108.144423%22%2C%22collections%22%3A%5B%22DEB5KWFS%22%2C%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22WJDNKBGA%22%2C%226IWM732K%22%2C%22CF4ZI7HM%22%2C%22N8397DCZ%22%2C%22J4NL8E8U%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A17%3A34Z%22%7D%7D%2C%7B%22key%22%3A%22MRJJ37GQ%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Pasquier%20and%20Alouani%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ER.%20Pasquier%2C%20M.%20Alouani%2C%20Calculated%20iron%20L2%2C3%20x-ray%20absorption%20and%20x-ray%20magnetic%20circular%20dichroism%20of%20spin-crossover%20Fe%28phen%292%28NCS%292%20molecules%20adsorbed%20on%20a%20Cu%28001%29%20surface%2C%20Physical%20Review%20B%20108%20%282023%29%20094423.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.094423%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1103%5C%2FPhysRevB.108.094423%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Calculated%20iron%20L2%2C3%20x-ray%20absorption%20and%20x-ray%20magnetic%20circular%20dichroism%20of%20spin-crossover%20Fe%28phen%292%28NCS%292%20molecules%20adsorbed%20on%20a%20Cu%28001%29%20surface%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22R.%22%2C%22lastName%22%3A%22Pasquier%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mebarek%22%2C%22lastName%22%3A%22Alouani%22%7D%5D%2C%22abstractNote%22%3A%22The%20projector%20augmented%20wave%20method%20has%20been%20used%20to%20compute%20the%20iron%20L-2%2CL-3%20edges%20of%20x-ray%20absorption%20spectra%20%28XAS%29%20and%20x-ray%20magnetic%20circular%20dichroism%20%28XMCD%29%20of%20the%20spin-crossover%20Fe%28phen%29%282%29%28NCS%29%282%29%20molecule%20when%20adsorbed%20on%20Cu%28001%29%20surface%20and%20in%20the%20gas%20phase%2C%20for%20both%20the%20high-spin%20%28HS%29%20and%20low-spin%20%28LS%29%20states.%20The%20electronic%20structures%20of%20both%20HS%20and%20LS%20states%20have%20been%20calculated%20using%20the%20spin-polarized%20generalized%20gradient%20approximation%20for%20the%20exchange-correlation%20potential%2C%20and%20the%20strongly%20localized%20iron%203d%20states%20are%20described%20using%20Dudarev%27s%20rotationally%20invariant%20formulation%20of%20the%20DFT%2BU%20method.%20It%20is%20shown%20that%20only%20the%20iron%20all-electron%20partial%20waves%20are%20necessary%20to%20calculate%20the%20XAS%20transition%20matrix%20elements%20in%20the%20electric%20dipole%20approximation%2C%20as%20the%20contribution%20of%20the%20pseudo%20partial%20waves%20is%20compensated%20by%20the%20plane-wave%20component%20of%20the%20wave%20function.%20It%20is%20found%20that%20the%20calculated%20XAS%20and%20XMCD%20with%20the%20static%20core%20hole%20or%20the%20Slater%20transition%20state%20half%20hole%20are%20in%20less%20good%20agreement%20with%20experiment%20than%20those%20using%20the%20so%20called%20initial%20state.%20This%20disagreement%20is%20due%20to%20the%20reduction%20of%20the%20iron%20spin%20magnetic%20moment%20caused%20by%20the%20static%20screening%20of%20the%20core%20hole%20by%20the%20photo-electron.%20The%20L%282%2C%293%20XAS%20formula%20is%20found%20to%20be%20directly%20related%20to%20the%20unoccupied%203d%20density%20of%20states%20%28DOS%29%2C%20and%20hence%20the%20symmetry%20broken%20e%28g%20%29and%20the%20t%282%29g%20iron%20DOS%20are%20used%20to%20explain%20the%20XAS%20and%20XMCD%20results.%20It%20is%20demonstrated%20that%20the%20dependence%20of%20the%20HS%20XMCD%20on%20the%20direction%20of%20incident%20x-ray%20circularly%20polarized%20light%20with%20respect%20to%20the%20magnetization%20direction%20can%20be%20used%20to%20determine%20the%20iron%20octahedron%20deformation%2C%20while%20the%20XMCD%20for%20various%20magnetization%20directions%20is%20directly%20related%20to%20the%20anisotropy%20of%20the%20orbital%20magnetic%20moment%20and%20the%20magnetocrystalline%20energy.%20The%20Thole-Carra-Van%20der%20Laan%20XMCD%20sum%20rules%20have%20been%20applied%20to%20the%20XMCD%20L-2%2CL-3%20spectra%20to%20compute%20the%20spin%20and%20orbital%20magnetic%20moments.%20It%20is%20shown%20that%20the%20magnetic%20dipole%20moment%20T-z%20is%20very%20large%20due%20to%20the%20strong%20distortion%20of%20the%20iron%20octahedron%20and%20is%20necessary%20for%20an%20accurate%20determination%20of%20the%20sum%20rule%20computed%20spin%20magnetic%20moment.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1103%5C%2FPhysRevB.108.094423%22%2C%22ISSN%22%3A%222469-9950%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22IUWT6S8X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A03%3A18Z%22%7D%7D%2C%7B%22key%22%3A%22BQJMWSXQ%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Percebois%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EG.J.%20Percebois%2C%20A.%20Lacerda-Santos%2C%20B.%20Brun%2C%20B.%20Hackens%2C%20X.%20Waintal%2C%20D.%20Weinmann%2C%20Reconstructing%20the%20potential%20configuration%20in%20a%20high-mobility%20semiconductor%20heterostructure%20with%20scanning%20gate%20microscopy%2C%20SciPost%20Physics%2015%20%282023%29%20242.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.21468%5C%2FSciPostPhys.15.6.242%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.21468%5C%2FSciPostPhys.15.6.242%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Reconstructing%20the%20potential%20configuration%20in%20a%20high-mobility%20semiconductor%20heterostructure%20with%20scanning%20gate%20microscopy%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gaetan%20J.%22%2C%22lastName%22%3A%22Percebois%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Antonio%22%2C%22lastName%22%3A%22Lacerda-Santos%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Boris%22%2C%22lastName%22%3A%22Brun%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Benoit%22%2C%22lastName%22%3A%22Hackens%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Xavier%22%2C%22lastName%22%3A%22Waintal%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Dietmar%22%2C%22lastName%22%3A%22Weinmann%22%7D%5D%2C%22abstractNote%22%3A%22The%20weak%20disorder%20potential%20seen%20by%20the%20electrons%20of%20a%20two-dimensional%20electron%20gas%20in%20high-mobility%20semiconductor%20heterostructures%20leads%20to%20fluctuations%20in%20the%20physical%20properties%20and%20can%20be%20an%20issue%20for%20nanodevices.%20In%20this%20paper%2C%20we%20show%20that%20a%20scanning%20gate%20microscopy%20%28SGM%29%20image%20contains%20information%20about%20the%20disorder%20potential%2C%20and%20that%20a%20machine%20learning%20approach%20based%20on%20SGM%20data%20can%20be%20used%20to%20determine%20the%20disorder.%20We%20reconstruct%20the%20electric%20potential%20of%20a%20sample%20from%20its%20experimental%20SGM%20data%20and%20validate%20the%20result%20through%20an%20estimate%20of%20its%20accuracy.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.21468%5C%2FSciPostPhys.15.6.242%22%2C%22ISSN%22%3A%222542-4653%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22EPW69HFA%22%5D%2C%22dateModified%22%3A%222024-09-10T14%3A57%3A41Z%22%7D%7D%2C%7B%22key%22%3A%22JVWHBDQC%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Pierini%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ES.%20Pierini%2C%20C.%20Abadie%2C%20T.H.%20Dang%2C%20A.%20Khalili%2C%20H.%20Zhang%2C%20M.%20Cavallo%2C%20Y.%20Prado%2C%20B.%20Gallas%2C%20S.%20Ithurria%2C%20S.%20Sauvage%2C%20J.F.%20Dayen%2C%20G.%20Vincent%2C%20E.%20Lhuillier%2C%20Lithium-Ion%20Glass%20Gating%20of%20HgTe%20Nanocrystal%20Film%20with%20Designed%20Light-Matter%20Coupling.%2C%20Materials%2016%20%282023%29%202335.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fma16062335%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fma16062335%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Lithium-Ion%20Glass%20Gating%20of%20HgTe%20Nanocrystal%20Film%20with%20Designed%20Light-Matter%20Coupling.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Stefano%22%2C%22lastName%22%3A%22Pierini%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Claire%22%2C%22lastName%22%3A%22Abadie%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tung%20Huu%22%2C%22lastName%22%3A%22Dang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Adrien%22%2C%22lastName%22%3A%22Khalili%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Huichen%22%2C%22lastName%22%3A%22Zhang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mariarosa%22%2C%22lastName%22%3A%22Cavallo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoann%22%2C%22lastName%22%3A%22Prado%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bruno%22%2C%22lastName%22%3A%22Gallas%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sandrine%22%2C%22lastName%22%3A%22Ithurria%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sebastien%22%2C%22lastName%22%3A%22Sauvage%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean%20Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Gregory%22%2C%22lastName%22%3A%22Vincent%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Emmanuel%22%2C%22lastName%22%3A%22Lhuillier%22%7D%5D%2C%22abstractNote%22%3A%22Nanocrystals%27%20%28NCs%29%20band%20gap%20can%20be%20easily%20tuned%20over%20the%20infrared%20range%2C%20making%20them%20appealing%20for%20the%20design%20of%20cost-effective%20sensors.%20Though%20their%20growth%20has%20reached%20a%20high%20level%20of%20maturity%2C%20their%20doping%20remains%20a%20poorly%20controlled%20parameter%2C%20raising%20the%20need%20for%20post-synthesis%20tuning%20strategies.%20As%20a%20result%2C%20phototransistor%20device%20geometry%20offers%20an%20interesting%20alternative%20to%20photoconductors%2C%20allowing%20carrier%20density%20control.%20Phototransistors%20based%20on%20NCs%20that%20target%20integrated%20infrared%20sensing%20have%20to%20%28i%29%20be%20compatible%20with%20low-temperature%20operation%2C%20%28ii%29%20avoid%20liquid%20handling%2C%20and%20%28iii%29%20enable%20large%20carrier%20density%20tuning.%20These%20constraints%20drive%20the%20search%20for%20innovative%20gate%20technologies%20beyond%20traditional%20dielectric%20or%20conventional%20liquid%20and%20ion%20gel%20electrolytes.%20Here%2C%20we%20explore%20lithium-ion%20glass%20gating%20and%20apply%20it%20to%20channels%20made%20of%20HgTe%20narrow%20band%20gap%20NCs.%20We%20demonstrate%20that%20this%20all-solid%20gate%20strategy%20is%20compatible%20with%20large%20capacitance%20up%20to%202%20F%5Cu00b7cm-2%20and%20can%20be%20operated%20over%20a%20broad%20range%20of%20temperatures%20%28130-300%20K%29.%20Finally%2C%20we%20tackle%20an%20issue%20often%20faced%20by%20NC-based%20phototransistors%3Atheir%20low%20absorption%3B%20from%20a%20metallic%20grating%20structure%2C%20we%20combined%20two%20resonances%20and%20achieved%20high%20responsivity%20%2810%20A%5Cu00b7W-1%20or%20an%20external%20quantum%20efficiency%20of%20500%25%29%20over%20a%20broadband%20spectral%20range.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.3390%5C%2Fma16062335%22%2C%22ISSN%22%3A%221996-1944%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.3390%5C%2Fma16062335%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A17%3A38Z%22%7D%7D%2C%7B%22key%22%3A%22JR2Y6D27%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Ram%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EA.%20Ram%2C%20K.%20Maity%2C%20C.%20Marchand%2C%20A.%20Mahmoudi%2C%20A.R.%20Kshirsagar%2C%20M.%20Soliman%2C%20T.%20Taniguchi%2C%20K.%20Watanabe%2C%20B.%20Doudin%2C%20A.%20Ouerghi%2C%20S.%20Reichardt%2C%20I.%20O%26%23x2019%3BConnor%2C%20J.-F.%20Dayen%2C%20Reconfigurable%20Multifunctional%20van%20der%20Waals%20Ferroelectric%20Devices%20and%20Logic%20Circuits.%2C%20ACS%20Nano%2017%20%282023%29%2021865%26%23x2013%3B21877.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsnano.3c07952%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsnano.3c07952%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Reconfigurable%20Multifunctional%20van%20der%20Waals%20Ferroelectric%20Devices%20and%20Logic%20Circuits.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ankita%22%2C%22lastName%22%3A%22Ram%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Krishna%22%2C%22lastName%22%3A%22Maity%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Cedric%22%2C%22lastName%22%3A%22Marchand%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Aymen%22%2C%22lastName%22%3A%22Mahmoudi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Aseem%20Rajan%22%2C%22lastName%22%3A%22Kshirsagar%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mohamed%22%2C%22lastName%22%3A%22Soliman%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Takashi%22%2C%22lastName%22%3A%22Taniguchi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Kenji%22%2C%22lastName%22%3A%22Watanabe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bernard%22%2C%22lastName%22%3A%22Doudin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Abdelkarim%22%2C%22lastName%22%3A%22Ouerghi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sven%22%2C%22lastName%22%3A%22Reichardt%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ian%22%2C%22lastName%22%3A%22O%27Connor%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%5D%2C%22abstractNote%22%3A%22Emerging%20reconfigurable%20devices%20are%20fast%20gaining%20popularity%20in%20the%20search%20for%20next-generation%20computing%20hardware%2C%20while%20ferroelectric%20engineering%20of%20the%20doping%20state%20in%20semiconductor%20materials%20has%20the%20potential%20to%20offer%20alternatives%20to%20traditional%20von-Neumann%20architecture.%20In%20this%20work%2C%20we%20combine%20these%20concepts%20and%20demonstrate%20the%20suitability%20of%20reconfigurable%20ferroelectric%20field-effect%20transistors%20%28Re-FeFETs%29%20for%20designing%20nonvolatile%20reconfigurable%20logic-in-memory%20circuits%20with%20multifunctional%20capabilities.%20Modulation%20of%20the%20energy%20landscape%20within%20a%20homojunction%20of%20a%202D%20tungsten%20diselenide%20%28WSe2%29%20layer%20is%20achieved%20by%20independently%20controlling%20two%20split-gate%20electrodes%20made%20of%20a%20ferroelectric%202D%20copper%20indium%20thiophosphate%20%28CuInP2S6%29%20layer.%20Controlling%20the%20state%20encoded%20in%20the%20program%20gate%20enables%20switching%20between%20p%2C%20n%2C%20and%20ambipolar%20FeFET%20operating%20modes.%20The%20transistors%20exhibit%20on-off%20ratios%20exceeding%20106%20and%20hysteresis%20windows%20of%20up%20to%2010%20V%20width.%20The%20homojunction%20can%20change%20from%20Ohmic-like%20to%20diode%20behavior%20with%20a%20large%20rectification%20ratio%20of%20104.%20When%20programmed%20in%20the%20diode%20mode%2C%20the%20large%20built-in%20p-n%20junction%20electric%20field%20enables%20efficient%20separation%20of%20photogenerated%20carriers%2C%20making%20the%20device%20attractive%20for%20energy-harvesting%20applications.%20The%20implementation%20of%20the%20Re-FeFET%20for%20reconfigurable%20logic%20functions%20shows%20how%20a%20circuit%20can%20be%20reconfigured%20to%20emulate%20either%20polymorphic%20ferroelectric%20NAND%5C%2FAND%20logic-in-memory%20or%20electronic%20XNOR%20logic%20with%20a%20long%20retention%20time%20exceeding%20104%20s.%20We%20also%20illustrate%20how%20a%20circuit%20design%20made%20of%20just%20two%20Re-FeFETs%20exhibits%20high%20logic%20expressivity%20with%20reconfigurability%20at%20runtime%20to%20implement%20several%20key%20nonvolatile%202-input%20logic%20functions.%20Moreover%2C%20the%20Re-FeFET%20circuit%20demonstrates%20high%20compactness%2C%20with%20an%20up%20to%2080%25%20reduction%20in%20transistor%20count%20compared%20to%20standard%20CMOS%20design.%20The%202D%20van%20de%20Waals%20Re-FeFET%20devices%20therefore%20exhibit%20promising%20potential%20for%20both%20More-than-Moore%20and%20beyond-Moore%20future%20of%20electronics%2C%20in%20particular%20for%20an%20energy-efficient%20implementation%20of%20in-memory%20computing%20and%20machine%20learning%20hardware%2C%20due%20to%20their%20multifunctionality%20and%20design%20compactness.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1021%5C%2Facsnano.3c07952%22%2C%22ISSN%22%3A%221936-086X%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1021%5C%2Facsnano.3c07952%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A17%3A43Z%22%7D%7D%2C%7B%22key%22%3A%22WPSDZPY9%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Semak%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ES.%20Semak%2C%20V.%20Kapustianyk%2C%20Y.%20Eliyashevskyy%2C%20O.%20Bovgyra%2C%20M.%20Kovalenko%2C%20U.%20Mostovoi%2C%20B.%20Doudin%2C%20B.%20Kundys%2C%20On%20the%20photovoltaic%20effect%20asymmetry%20in%20ferroelectrics.%2C%20Journal%20of%20Physics.%20Condensed%20Matter%26%23x202F%3B%3A%20An%20Institute%20of%20Physics%20Journal%2035%20%282023%29%20094001.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1088%5C%2F1361-648X%5C%2Faca579%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1088%5C%2F1361-648X%5C%2Faca579%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22On%20the%20photovoltaic%20effect%20asymmetry%20in%20ferroelectrics.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22S%22%2C%22lastName%22%3A%22Semak%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V%22%2C%22lastName%22%3A%22Kapustianyk%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yu%22%2C%22lastName%22%3A%22Eliyashevskyy%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22O%22%2C%22lastName%22%3A%22Bovgyra%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M%22%2C%22lastName%22%3A%22Kovalenko%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22U%22%2C%22lastName%22%3A%22Mostovoi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bernard%22%2C%22lastName%22%3A%22Doudin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%5D%2C%22abstractNote%22%3A%22Despite%20symmetrical%20polarization%2C%20the%20magnitude%20of%20a%20light-induced%20voltage%20is%20known%20to%20be%20asymmetric%20with%20respect%20to%20poling%20sign%20in%20many%20photovoltaic%20%28PV%29%20ferroelectrics%20%28FEs%29.%20This%20asymmetry%20remains%20unclear%20and%20is%20often%20attributed%20to%20extrinsic%20effects.%20We%20show%20here%20for%20the%20first%20time%20that%20such%20an%20asymmetry%20can%20be%20intrinsic%2C%20steaming%20from%20the%20superposition%20of%20asymmetries%20of%20internal%20FE%20bias%20and%20electro-piezo-strictive%20deformation.%20This%20hypothesis%20is%20confirmed%20by%20the%20observed%20decrease%20of%20PV%20asymmetry%20for%20smaller%20FE%20bias.%20Moreover%2C%20the%20both%20PV%20effect%20and%20remanent%20polarization%20are%20found%20to%20increase%20under%20vacuum-induced%20expansion%20and%20to%20decrease%20for%20gas-induced%20compression%2C%20with%20tens%20percents%20tunability.%20The%20change%20in%20cations%20positions%20under%20pressure%20is%20analysed%20through%20the%20first-principle%20density%20functional%20theory%20calculations.%20The%20reported%20properties%20provide%20key%20insight%20for%20FE-based%20solar%20elements%20optimization.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1088%5C%2F1361-648X%5C%2Faca579%22%2C%22ISSN%22%3A%221361-648X%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1088%5C%2F1361-648X%5C%2Faca579%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A17%3A48Z%22%7D%7D%2C%7B%22key%22%3A%22ZNB9VYQY%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Soliman%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20Soliman%2C%20K.%20Maity%2C%20A.%20Gloppe%2C%20A.%20Mahmoudi%2C%20A.%20Ouerghi%2C%20B.%20Doudin%2C%20B.%20Kundys%2C%20J.-F.%20Dayen%2C%20Photoferroelectric%20All-van-der-Waals%20Heterostructure%20for%20Multimode%20Neuromorphic%20Ferroelectric%20Transistors.%2C%20ACS%20Applied%20Materials%20%26amp%3B%20Interfaces%2015%20%282023%29%2015732%26%23x2013%3B15744.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsami.3c00092%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1021%5C%2Facsami.3c00092%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Photoferroelectric%20All-van-der-Waals%20Heterostructure%20for%20Multimode%20Neuromorphic%20Ferroelectric%20Transistors.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mohamed%22%2C%22lastName%22%3A%22Soliman%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Krishna%22%2C%22lastName%22%3A%22Maity%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Arnaud%22%2C%22lastName%22%3A%22Gloppe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Aymen%22%2C%22lastName%22%3A%22Mahmoudi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Abdelkarim%22%2C%22lastName%22%3A%22Ouerghi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bernard%22%2C%22lastName%22%3A%22Doudin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bohdan%22%2C%22lastName%22%3A%22Kundys%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Francois%22%2C%22lastName%22%3A%22Dayen%22%7D%5D%2C%22abstractNote%22%3A%22Interface-driven%20effects%20in%20ferroelectric%20van%20der%20Waals%20%28vdW%29%20heterostructures%20provide%20fresh%20opportunities%20in%20the%20search%20for%20alternative%20device%20architectures%20toward%20overcoming%20the%20von%20Neumann%20bottleneck.%20However%2C%20their%20implementation%20is%20still%20in%20its%20infancy%2C%20mostly%20by%20electrical%20control.%20It%20is%20of%20utmost%20interest%20to%20develop%20strategies%20for%20additional%20optical%20and%20multistate%20control%20in%20the%20quest%20for%20novel%20neuromorphic%20architectures.%20Here%2C%20we%20demonstrate%20the%20electrical%20and%20optical%20control%20of%20the%20ferroelectric%20polarization%20states%20of%20ferroelectric%20field%20effect%20transistors%20%28FeFET%29.%20The%20FeFETs%2C%20fully%20made%20of%20ReS2%5C%2FhBN%5C%2FCuInP2S6%20vdW%20materials%2C%20achieve%20an%20on%5C%2Foff%20ratio%20exceeding%20107%2C%20a%20hysteresis%20memory%20window%20up%20to%207%20V%20wide%2C%20and%20multiple%20remanent%20states%20with%20a%20lifetime%20exceeding%20103%20s.%20Moreover%2C%20the%20ferroelectric%20polarization%20of%20the%20CuInP2S6%20%28CIPS%29%20layer%20can%20be%20controlled%20by%20photoexciting%20the%20vdW%20heterostructure.%20We%20perform%20wavelength-dependent%20studies%2C%20which%20allow%20for%20identifying%20two%20mechanisms%20at%20play%20in%20the%20optical%20control%20of%20the%20polarization%3A%20band-to-band%20photocarrier%20generation%20into%20the%202D%20semiconductor%20ReS2%20and%20photovoltaic%20voltage%20into%20the%202D%20ferroelectric%20CIPS.%20Finally%2C%20heterosynaptic%20plasticity%20is%20demonstrated%20by%20operating%20our%20FeFET%20in%20three%20different%20synaptic%20modes%3A%20electrically%20stimulated%2C%20optically%20stimulated%2C%20and%20optically%20assisted%20synapse.%20Key%20synaptic%20functionalities%20are%20emulated%20including%20electrical%20long-term%20plasticity%2C%20optoelectrical%20plasticity%2C%20optical%20potentiation%2C%20and%20spike%20rate-dependent%20plasticity.%20The%20simulated%20artificial%20neural%20networks%20demonstrate%20an%20excellent%20accuracy%20level%20of%2091%25%20close%20to%20ideal-model%20synapses.%20These%20results%20provide%20a%20fresh%20background%20for%20future%20research%20on%20photoferroelectric%20vdW%20systems%20and%20put%20ferroelectric%20vdW%20heterostructures%20on%20the%20roadmap%20for%20the%20next%20neuromorphic%20computing%20architectures.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1021%5C%2Facsami.3c00092%22%2C%22ISSN%22%3A%221944-8252%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1021%5C%2Facsami.3c00092%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%22J4NL8E8U%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-18T12%3A02%3A33Z%22%7D%7D%2C%7B%22key%22%3A%22U662J3QU%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Souissi%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A0%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EM.%20Souissi%2C%20G.%20Schmerber%2C%20S.%20Colis%2C%20M.%20Alruwaili%2C%20Study%20of%20Zn1-2xNixFexO%20thin%20films%20coated%20on%20glass%20by%20sol-gel%20spin-coating%20method%20for%20DMS%20materials%2C%20European%20Physical%20Journal%20Plus%20138%20%282023%29.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1140%5C%2Fepjp%5C%2Fs13360-023-04312-7%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1140%5C%2Fepjp%5C%2Fs13360-023-04312-7%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Study%20of%20Zn1-2xNixFexO%20thin%20films%20coated%20on%20glass%20by%20sol-gel%20spin-coating%20method%20for%20DMS%20materials%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Souissi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guy%22%2C%22lastName%22%3A%22Schmerber%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Silviu%22%2C%22lastName%22%3A%22Colis%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%22%2C%22lastName%22%3A%22Alruwaili%22%7D%5D%2C%22abstractNote%22%3A%22In%20this%20paper%2C%20un-%2C%20Fe-%2C%20Ni-%20and%20%28Fe%20%2B%20Ni%29-doped%20ZnO%20layers%20were%20grown%20on%20transparent%20glass%20substrates%20by%20sol-gel%20process%20using%20the%20spin-coating%20technique.%20Investigations%20based%20on%20different%20techniques%20such%20as%20XRD%2C%20SEM%2C%20UV-visible%20spectroscopy%2C%20PL%20and%20VSM%20were%20performed%20to%20analyze%20the%20samples.%20X-ray%20diffraction%20%28XRD%29%20analysis%20revealed%20the%20formation%20of%20hexagonal%20structure%20corresponding%20to%20the%20wurtzite%20phase%20of%20all%20samples%20without%20any%20secondary%20phases%20present%20in%20the%20spectra.%20The%20average%20crystallite%20size%20is%20in%2036-80%20nm%20range.%20Scanning%20electron%20microscopy%20%28SEM%29%20investigation%20of%20the%20layers%20reveals%20that%20following%20doping%2C%20the%20ZnO%20grain%20sizes%20tend%20to%20increase.%20UV-visible%20shows%20red%20shift%20in%20peak%20wavelength.%20These%20findings%20are%20in%20line%20with%20the%20grain%20size%20dependence%20after%20doping%20obtained%20from%20XRD.%20Using%20transmittance%20spectra%2C%20the%20optical%20energy%20bandgap%20was%20found%203.29%2C%203.17%2C%203.11%20and%203.15%20eV%20of%20un-%2C%20Fe-%2C%20Ni-%20and%20%28Ni%20%2B%20Fe%29-doped%20ZnO%2C%20respectively.%20Un-doped%20ZnO%20has%20the%20highest%20intensity%20in%20near-band-edge%20emission%2C%20according%20to%20photoluminescence%20%28PL%29%20spectra%2C%20but%20after%20Ni%20and%20Fe%20doping%2C%20a%20slight%20redshift%20is%20observed%20with%20a%20strong%20violet%20%28423%20nm%29%20and%20blue%20%28475%20nm%29%20emission%20peaks%2C%20respectively.%20Hence%2C%20for%20Zn1-2xNixFexO%20%28x%20%3D%200.01%20and%200.03%20mol%25%29%20thin%20films%2C%20the%20ensuing%20emission%20properties%20make%20them%20appropriate%20as%20lighting%20sources.%20Consequently%2C%20it%20is%20anticipated%20that%20full-color%20display%20devices%20would%20be%20possible.%20Vibrating%20sample%20magnetometer%20%28VSM%29%20measurements%20at%20room%20temperature%20are%20discovered%20to%20be%20hysteretic%2C%20indicating%20room%20temperature%20ferromagnetism%20%28RTFM%29%20and%20implying%20the%20Curie%20temperature%20is%20greater%20than%20300%20K.%20The%20area%20under%20the%20hysteresis%20loop%20of%20Zn1-2xNixFexO%20%28x%20%3D%200.01%20and%200.03%20mol%25%29%20decreases%2C%20indicating%20low%20hysteresis%20loss.%20The%20present%20findings%20are%20suitable%20for%20spintronic%20applications.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1140%5C%2Fepjp%5C%2Fs13360-023-04312-7%22%2C%22ISSN%22%3A%222190-5444%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1140%5C%2Fepjp%5C%2Fs13360-023-04312-7%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22ZN5EITAC%22%2C%22CF4ZI7HM%22%2C%22SB8Q592R%22%5D%2C%22dateModified%22%3A%222024-06-03T09%3A39%3A20Z%22%7D%7D%2C%7B%22key%22%3A%22CB2MA9B7%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Temdie%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EL.%20Temdie%2C%20V.%20Castel%2C%20C.%20Dubs%2C%20G.%20Pradhan%2C%20J.%20Solano%2C%20H.%20Majjad%2C%20R.%20Bernard%2C%20Y.%20Henry%2C%20M.%20Bailleul%2C%20V.%20Vlaminck%2C%20High%20wave%20vector%20non-reciprocal%20spin%20wave%20beams%2C%20AIP%20Advances%2013%20%282023%29%20025207.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F9.0000535%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F9.0000535%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22High%20wave%20vector%20non-reciprocal%20spin%20wave%20beams%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22L.%22%2C%22lastName%22%3A%22Temdie%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V.%22%2C%22lastName%22%3A%22Castel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22C.%22%2C%22lastName%22%3A%22Dubs%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22G.%22%2C%22lastName%22%3A%22Pradhan%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jos%5Cu00e9%22%2C%22lastName%22%3A%22Solano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hicham%22%2C%22lastName%22%3A%22Majjad%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Romain%22%2C%22lastName%22%3A%22Bernard%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yves%22%2C%22lastName%22%3A%22Henry%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matthieu%22%2C%22lastName%22%3A%22Bailleul%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V.%22%2C%22lastName%22%3A%22Vlaminck%22%7D%5D%2C%22abstractNote%22%3A%22We%20report%20unidirectional%20transmission%20of%20micron-wide%20spin%20waves%20beams%20in%20a%2055%20nm%20thin%20YIG.%20We%20downscaled%20a%20chiral%20coupling%20technique%20implementing%20Ni80Fe20%20nanowires%20arrays%20with%20different%20widths%20and%20lattice%20spacing%20to%20study%20the%20non-reciprocal%20transmission%20of%20exchange%20spin%20waves%20down%20to%20lambda%20asymptotic%20to%2080%20nm.%20A%20full%20spin%20wave%20spectroscopy%20analysis%20of%20these%20high%20wavevector%20coupled-modes%20shows%20some%20difficulties%20to%20characterize%20their%20propagation%20properties%2C%20due%20to%20both%20the%20non-monotonous%20field%20dependence%20of%20the%20coupling%20efficiency%2C%20and%20also%20the%20inhomogeneous%20stray%20field%20from%20the%20nanowires.%20%28c%29%202023%20Author%28s%29.%20All%20article%20content%2C%20except%20where%20otherwise%20noted%2C%20is%20licensed%20under%20a%20Creative%20Commons%20Attribution%20%28CC%20BY%29%20license%20%28http%3A%5C%2F%5C%2Fcreativecommons.org%5C%2Flicenses%5C%2Fby%5C%2F4.0%5C%2F%29.%20https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F9.0000535%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F9.0000535%22%2C%22ISSN%22%3A%222158-3226%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F9.0000535%22%2C%22collections%22%3A%5B%22QK933HES%22%2C%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A18%3A17Z%22%7D%7D%2C%7B%22key%22%3A%22S3KQMYKY%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Temdie%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EL.%20Temdie%2C%20V.%20Castel%2C%20T.%20Reimann%2C%20M.%20Lindner%2C%20C.%20Dubs%2C%20G.%20Pradhan%2C%20J.%20Solano%2C%20R.%20Bernard%2C%20H.%20Majjad%2C%20Y.%20Henry%2C%20M.%20Bailleul%2C%20V.%20Vlaminck%2C%20Chiral%20Excitation%20of%20Exchange%20Spin%20Waves%20Using%20Gold%20Nanowire%20Grating%2C%20Magnetochemistry%209%20%282023%29%20199.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fmagnetochemistry9080199%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fmagnetochemistry9080199%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Chiral%20Excitation%20of%20Exchange%20Spin%20Waves%20Using%20Gold%20Nanowire%20Grating%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22L%22%2C%22lastName%22%3A%22Temdie%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V%22%2C%22lastName%22%3A%22Castel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22T%22%2C%22lastName%22%3A%22Reimann%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M%22%2C%22lastName%22%3A%22Lindner%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22C%22%2C%22lastName%22%3A%22Dubs%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22G%22%2C%22lastName%22%3A%22Pradhan%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jose%22%2C%22lastName%22%3A%22Solano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22R%22%2C%22lastName%22%3A%22Bernard%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hicham%22%2C%22lastName%22%3A%22Majjad%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yves%22%2C%22lastName%22%3A%22Henry%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mathieu%22%2C%22lastName%22%3A%22Bailleul%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Vincent%22%2C%22lastName%22%3A%22Vlaminck%22%7D%5D%2C%22abstractNote%22%3A%22We%20propose%20an%20experimental%20method%20for%20the%20unidirectional%20excitation%20of%20spin%20waves.%20By%20structuring%20Au%20nanowire%20arrays%20within%20a%20coplanar%20waveguide%20onto%20a%20thin%20yttrium%20iron%20garnet%20%28YIG%29%20film%2C%20we%20observe%20a%20chiral%20coupling%20between%20the%20excitation%20field%20geometry%20of%20the%20nanowire%20grating%20and%20several%20well-resolved%20propagating%20magnon%20modes.%20We%20report%20a%20propagating%20spin%20wave%20spectroscopy%20study%20with%20unprecedented%20spectral%20definition%2C%20wavelengths%20down%20to%20130nm%20and%20attenuation%20lengths%20well%20above%20100%20mu%20m%20over%20the%2020GHz%20frequency%20band.%20The%20proposed%20experiment%20paves%20the%20way%20for%20future%20non-reciprocal%20magnonic%20devices.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.3390%5C%2Fmagnetochemistry9080199%22%2C%22ISSN%22%3A%222312-7481%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.3390%5C%2Fmagnetochemistry9080199%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A18%3A11Z%22%7D%7D%2C%7B%22key%22%3A%22TAFLE9BR%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Tuerhong%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ER.%20Tuerhong%2C%20F.%20Ngassam%2C%20M.%20Alouani%2C%20J.-P.%20Bucher%2C%20When%20Molecular%20Dimerization%20Induces%20Magnetic%20Bi-Stability%20at%20the%20Metal-Organic%20Interface%2C%20Advanced%20Physics%20Research%202%20%282023%29%202200005.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1002%5C%2Fapxr.202200005%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1002%5C%2Fapxr.202200005%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22When%20Molecular%20Dimerization%20Induces%20Magnetic%20Bi-Stability%20at%20the%20Metal-Organic%20Interface%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Rouzhaji%22%2C%22lastName%22%3A%22Tuerhong%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Franck%22%2C%22lastName%22%3A%22Ngassam%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mebarek%22%2C%22lastName%22%3A%22Alouani%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Pierre%22%2C%22lastName%22%3A%22Bucher%22%7D%5D%2C%22abstractNote%22%3A%222D%20metal-organic%20frameworks%20have%20been%20recently%20proposed%20as%20a%20flexible%20platform%20for%20realizing%20new%20functional%20materials%20including%20quantum%20phases.%20Here%2C%20we%20present%20a%20method%20to%20create%20metal-organic%20dimer%20complexes%20by%20on-surface%20assembly%20on%20a%20metal%20substrate%20using%20low-temperature%20scanning%20tunneling%20microscopy%20%28STM%29%20and%20spectroscopy%20%28STS%29.%20We%20demonstrate%20that%20a%20dimer%20of%20Mn-Phthalocyanine%20%28MnPc%292%20on%20a%20Ag%28111%29%20surface%20can%20be%20switched%20between%20two%20stable%20configurations%20upon%20a%20small%20conformational%20change%20controlled%20by%20STM%20manipulation.%20By%20means%20of%20density-functional%20theory%20calculations%2C%20it%20is%20found%20that%20the%20two%20conformations%20correspond%20to%20an%20antiferromagnetic%20%28AFM%29%20and%20a%20ferromagnetic%20%28FM%29%20state%20respectively.%20Directly%20coordinated%20Mn%20atoms%20of%20the%20dimer%20lead%20to%20an%20AFM-coupling%20whereas%20indirectly%20coordinated%20%28shifted%29%20Mn%20atoms%20lead%20to%20a%20FM-coupling.%20Rarely%20seen%20in%20a%20molecular-dimers%20with%20transition-metal%20atoms%2C%20the%20FM-AFM-FM%20transition%20is%20thus%20readily%20on-surface%20accessible.%20Furthermore%2C%20the%20two%20configurations%20of%20the%20switch%20are%20easily%20identified%20by%20their%20Kondo%20states%2C%20opening%20interesting%20routes%20in%20terms%20of%20both%2C%20writing%20%28FM%20versus%20AFM%20states%29%20and%20reading.%20These%20results%20pave%20the%20experimental%20route%20toward%20dimer-based%20materials%20with%20complex%20magnetic%20structures%20of%20potential%20interest%20for%20application%20in%20spintronics%2C%20logics%20and%20computing.On-surface%20assembled%20dimers%20of%20Mn-Phthalocyanine%20%28MnPc%292%20can%20be%20reversibly%20switched%20between%20an%20antiferromagnetic%20and%20a%20ferromagnetic%20state%20upon%20a%20small%20conformational%20change%20controlled%20by%20STM%20manipulation.%20The%20two%20states%20of%20the%20molecular%20switch%20are%20easily%20identified%20spectroscopically%20by%20their%20Kondo%20resonance%2C%20opening%20interesting%20routes%20for%20applications%20in%20molecular%20spintronics%2C%20logics%20and%20computing.%20image%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1002%5C%2Fapxr.202200005%22%2C%22ISSN%22%3A%222751-1200%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1002%5C%2Fapxr.202200005%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22RZX792Q8%22%2C%22IUWT6S8X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A03%3A25Z%22%7D%7D%2C%7B%22key%22%3A%22IPC6LFQR%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Vlaminck%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EV.%20Vlaminck%2C%20L.%20Temdie%2C%20V.%20Castel%2C%20M.B.%20Jungfleisch%2C%20D.%20Stoeffler%2C%20Y.%20Henry%2C%20M.%20Bailleul%2C%20Spin%20wave%20diffraction%20model%20for%20perpendicularly%20magnetized%20films%2C%20Journal%20of%20Applied%20Physics%20133%20%282023%29%20053903.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0128666%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0128666%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Spin%20wave%20diffraction%20model%20for%20perpendicularly%20magnetized%20films%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V.%22%2C%22lastName%22%3A%22Vlaminck%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22L.%22%2C%22lastName%22%3A%22Temdie%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V.%22%2C%22lastName%22%3A%22Castel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22M.%20B.%22%2C%22lastName%22%3A%22Jungfleisch%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Daniel%22%2C%22lastName%22%3A%22Stoeffler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yves%22%2C%22lastName%22%3A%22Henry%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matthieu%22%2C%22lastName%22%3A%22Bailleul%22%7D%5D%2C%22abstractNote%22%3A%22We%20present%20a%20near-field%20diffraction%20model%20for%20spin%20waves%20in%20perpendicularly%20magnetized%20films%20applicable%20in%20any%20geometries%20of%20excitation%20fields.%20This%20model%20relies%20on%20Kalinikos-Slavin%20formalism%20to%20express%20the%20dynamic%20susceptibility%20tensor%20in%20k-space%20and%20calculate%20the%20diffraction%20patterns%20via%20inverse%202D-Fourier%20transform%20of%20the%20response%20functions.%20We%20show%20an%20excellent%20quantitative%20agreement%20between%20our%20model%20and%20MuMax3%20micro-magnetic%20simulations%20on%20two%20different%20geometries%20of%20antennas.%20Our%20method%20benchmarks%20spin%20wave%20diffraction%20in%20perpendicularly%20magnetized%20films%20and%20is%20readily%20applicable%20for%20future%20designs%20of%20magnon%20beamforming%20and%20interferometric%20devices.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0128666%22%2C%22ISSN%22%3A%220021-8979%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0128666%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A01%3A14Z%22%7D%7D%2C%7B%22key%22%3A%226XGTDWTC%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Vollondat%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3ER.%20Vollondat%2C%20D.%20Stoeffler%2C%20D.%20Preziosi%2C%20S.%20Roques%2C%20A.%20Slaoui%2C%20T.%20Fix%2C%20Tunability%20of%20silicon%20clathrate%20film%20properties%20by%20controlled%20guest-occupation%20of%20their%20cages.%2C%20Journal%20of%20Chemical%20Physics%20158%20%282023%29%20164709.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0143828%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1063%5C%2F5.0143828%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Tunability%20of%20silicon%20clathrate%20film%20properties%20by%20controlled%20guest-occupation%20of%20their%20cages.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Romain%22%2C%22lastName%22%3A%22Vollondat%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Daniel%22%2C%22lastName%22%3A%22Stoeffler%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Daniele%22%2C%22lastName%22%3A%22Preziosi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Stephane%22%2C%22lastName%22%3A%22Roques%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Abdelilah%22%2C%22lastName%22%3A%22Slaoui%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Thomas%22%2C%22lastName%22%3A%22Fix%22%7D%5D%2C%22abstractNote%22%3A%22Type%20I%20and%20type%20II%20silicon%20clathrates%20are%20guest-host%20structures%20made%20of%20silicon%20polyhedral%20cages%20large%20enough%20to%20contain%20atoms%20that%20can%20be%20either%20inserted%20or%20evacuated%20with%20only%20a%20slight%20volume%20change%20of%20the%20structure.%20This%20feature%20is%20of%20interest%20not%20only%20for%20batteries%20or%20storage%20applications%20but%20also%20for%20tuning%20the%20properties%20of%20the%20silicon%20clathrate%20films.%20The%20thermal%20decomposition%20process%20can%20be%20tuned%20to%20obtain%20Na8Si46%20and%20Na2%3Cx%3C10Si136%20silicon%20clathrate%20films%20on%20intrinsic%20and%20p-type%20c-Si%20%28001%29%20wafer.%20Here%2C%20from%20a%20unique%20synthesized%20NaxSi136%20film%2C%20a%20range%20of%20resistivity%20of%20minimum%20four%20order%20of%20magnitude%20is%20possible%20by%20using%20post-synthesis%20treatments%2C%20switching%20from%20metallic%20to%20semiconductor%20behavior%20as%20the%20Na%20content%20is%20lowered.%20Extended%20exposition%20to%20sodium%20vapor%20allows%20us%20to%20obtain%20fully%20occupied%20Na24Si136%20metallic%20films%2C%20and%20annealing%20under%20iodine%20vapor%20is%20a%20way%20to%20reach%20the%20guest-free%20Si136%2C%20a%20semiconducting%20metastable%20form%20of%20silicon%20with%20a%201.9eV%20direct%20bandgap.%20Electrical%20measurements%20and%20resistance%20vs%20temperature%20measurements%20of%20the%20silicon%20clathrate%20films%20further%20discriminate%20the%20behavior%20of%20the%20various%20materials%20as%20the%20Na%20concentration%20is%20changing%2C%20additionally%20shouldered%20by%20density%20functional%20theory%20calculations%20for%20various%20guest%20occupations%2C%20further%20motivating%20the%20urge%20of%20an%20innovative%20pathway%20toward%20true%20guest-free%20type%20I%20and%20type%20II%20silicon%20clathrates.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1063%5C%2F5.0143828%22%2C%22ISSN%22%3A%221089-7690%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1063%5C%2F5.0143828%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%222A2F8AAB%22%2C%22CF4ZI7HM%22%2C%22SB8Q592R%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A01%3A19Z%22%7D%7D%2C%7B%22key%22%3A%22HVTZ3AZK%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Vu%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EV.-B.%20Vu%2C%20J.L.%20Bubendorff%2C%20L.D.N.%20Mouafo%2C%20S.%20Latil%2C%20A.%20Zaarour%2C%20J.-F.%20Dayen%2C%20L.%20Simon%2C%20Y.J.%20Dappe%2C%20Graphene%5C%2Faluminum%20oxide%20interfaces%20for%20nanoelectronic%20devices%2C%20Electronic%20Structure%205%20%282023%29%20045005.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1088%5C%2F2516-1075%5C%2Facff9e%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1088%5C%2F2516-1075%5C%2Facff9e%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Graphene%5C%2Faluminum%20oxide%20interfaces%20for%20nanoelectronic%20devices%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22V-B%22%2C%22lastName%22%3A%22Vu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22J.%20L.%22%2C%22lastName%22%3A%22Bubendorff%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22L.%20D.%20N.%22%2C%22lastName%22%3A%22Mouafo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22S.%22%2C%22lastName%22%3A%22Latil%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22A.%22%2C%22lastName%22%3A%22Zaarour%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Fran%5Cu00e7ois%22%2C%22lastName%22%3A%22Dayen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22L.%22%2C%22lastName%22%3A%22Simon%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Y.%20J.%22%2C%22lastName%22%3A%22Dappe%22%7D%5D%2C%22abstractNote%22%3A%22In%20this%20work%2C%20we%20study%20theoretically%20and%20experimentally%20graphene%5C%2Faluminum%20oxide%20interfaces%20as%200D%5C%2F2D%20interfaces%20for%20quantum%20electronics%20as%20the%20nature%20of%20the%20interface%20is%20of%20paramount%20importance%20to%20understand%20the%20quantum%20transport%20mechanism.%20Indeed%2C%20the%20electronic%20transport%20is%20driven%20either%20by%20a%20channel%20arising%20from%20a%20strong%20hybridization%20at%20the%20interface%2C%20or%20by%20tunneling%20across%20a%20van%20der%20Waals%20interface%2C%20with%20very%20different%20electric%20characteristics.%20By%20combining%20electronic%20spectroscopy%20and%20scanning%20microscopy%20with%20density%20functional%20theory%20calculations%2C%20we%20show%20that%20the%20interface%20is%20of%20weak%20and%20van%20der%20Waals%20nature.%20Quantum%20transport%20measurements%20in%20a%20single%20electron%20transistor%20confirm%20this%20result.%20Our%20results%20provide%20a%20first%20insight%20into%20the%20interfacial%20properties%20van%20der%20Waals%20materials%20based%20single%20electron%20device%2C%20and%20the%20key%20role%20played%20by%20the%20control%20of%20the%20interface%20states.%20The%20weak%20van%20der%20Waals%20coupling%20reported%20is%20promising%20for%20single%20electron%20device%2C%20where%20the%20control%20of%20the%20environmental%20charges%20is%20known%20to%20be%20a%20key%20challenge%20towards%20applications.%20Moreover%2C%20the%20unique%20vertical%20device%20architecture%2C%20enabled%20by%20the%20dual%20role%20of%20graphene%20including%20its%20vertical%20electric%20field%20transparency%2C%20opens%20the%20doors%20for%20a%20new%20class%20of%20single%20electron%20devices%20with%20higher%20scaling%20capability%20and%20functionalities.%20This%20work%20paves%20the%20way%20to%20new%20atomic%20environment%20control%20in%20single%20electron%20device.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1088%5C%2F2516-1075%5C%2Facff9e%22%2C%22ISSN%22%3A%222516-1075%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1088%5C%2F2516-1075%5C%2Facff9e%22%2C%22collections%22%3A%5B%22UVN4N32C%22%2C%22N8397DCZ%22%2C%225T5YGD4D%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A18%3A42Z%22%7D%7D%2C%7B%22key%22%3A%22B5GK5PS6%22%2C%22library%22%3A%7B%22id%22%3A1839302%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Weiss%20et%20al.%22%2C%22parsedDate%22%3A%222023%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%20style%3D%5C%22clear%3A%20left%3B%20%5C%22%3E%5Cn%20%20%20%20%3Cdiv%20class%3D%5C%22csl-left-margin%5C%22%20style%3D%5C%22float%3A%20left%3B%20padding-right%3A%200.5em%3B%20text-align%3A%20right%3B%20width%3A%201em%3B%5C%22%3E%5B1%5D%3C%5C%2Fdiv%3E%3Cdiv%20class%3D%5C%22csl-right-inline%5C%22%20style%3D%5C%22margin%3A%200%20.4em%200%201.5em%3B%5C%22%3EC.%20Weiss%2C%20M.%20Grassi%2C%20Y.%20Roussigne%2C%20A.%20Stashkevich%2C%20T.%20Schefer%2C%20J.%20Robert%2C%20M.%20Bailleul%2C%20M.%20Kostylev%2C%20Excitation%20and%20reception%20of%20magnetostatic%20surface%20spin%20waves%20in%20thin%20conducting%20ferromagnetic%20films%20by%20coplanar%20microwave%20antennas.%20Part%20II%3A%20Experiment%2C%20Journal%20of%20Magnetism%20and%20Magnetic%20Materials%20565%20%282023%29%20170002.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.jmmm.2022.170002%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.jmmm.2022.170002%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%20%20%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Excitation%20and%20reception%20of%20magnetostatic%20surface%20spin%20waves%20in%20thin%20conducting%20ferromagnetic%20films%20by%20coplanar%20microwave%20antennas.%20Part%20II%3A%20Experiment%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Charles%22%2C%22lastName%22%3A%22Weiss%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matias%22%2C%22lastName%22%3A%22Grassi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yves%22%2C%22lastName%22%3A%22Roussigne%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Andrey%22%2C%22lastName%22%3A%22Stashkevich%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Thomas%22%2C%22lastName%22%3A%22Schefer%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jerome%22%2C%22lastName%22%3A%22Robert%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matthieu%22%2C%22lastName%22%3A%22Bailleul%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mikhail%22%2C%22lastName%22%3A%22Kostylev%22%7D%5D%2C%22abstractNote%22%3A%22We%20report%20on%20propagating%20spin-wave%20spectroscopy%20measurements%20carried%20out%20on%20coplanar%20nano-antenna%20devices%20made%20from%20a%20Si%5C%2FSiO2%5C%2FRu%285%20nm%29%5C%2FCo%2820%29%5C%2FPt%285%20nm%29%20film.%20The%20measurements%20were%20analyzed%20in%20detail%20by%20employing%20newly%20developed%20theoretical%20modeling%20and%20de-embedding%20procedures.%20The%20magnetic%20parameters%20of%20the%20film%20were%20determined%20by%20complementary%20Brillouin%20light%20scattering%20and%20ferromagnetic%20resonance%20measurements.%20The%20propagating%20spin%20wave%20signals%20could%20be%20accounted%20for%20quantitatively%20for%20the%20range%20of%20externally%20applied%20magnetic%20fields%20investigated%20in%20this%20study%3A%20130-1500%20Oe.%22%2C%22date%22%3A%222023%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.1016%5C%2Fj.jmmm.2022.170002%22%2C%22ISSN%22%3A%220304-8853%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fdx.doi.org%5C%2F10.1016%5C%2Fj.jmmm.2022.170002%22%2C%22collections%22%3A%5B%22UJZN2BUR%22%2C%22UVN4N32C%22%2C%22GA3EX26X%22%5D%2C%22dateModified%22%3A%222024-09-11T07%3A01%3A24Z%22%7D%7D%5D%7D
[1]
U. Acevedo-Salas, B. Croes, Y. Zhang, O. Crégut, K.D. Dorkenoo, B. Kirbus, E. Singh, H. Beccard, M. Rusing, L.M. Eng, R. Hertel, E.A. Eliseev, A.N. Morozovska, S. Cherifi-Hertel, Impact of 3D Curvature on the Polarization Orientation in Non-Ising Domain Walls., Nano Letters 23 (2023) 795–803. https://doi.org/10.1021/acs.nanolett.2c03579.
[1]
N. Ahmed, R. Deffley, B. Kundys, N.A. Morley, 3D printing of magnetostrictive property in 17/4 ph stainless steel, Journal of Magnetism and Magnetic Materials 585 (2023) 171115. https://doi.org/10.1016/j.jmmm.2023.171115.
[1]
B.A. Ali, A. Bouhmouche, L. Wendling, C. Hu, C. Bouillet, G. Schmerber, A.M. Saeedi, S. Zafeiratos, V. Papaefthimiou, R. Moubah, S. Colis, Impact of film thickness on the structural, linear and non-linear optical properties of ferroelectric Bi2FeCrO6 perovskite thin films, Vacuum 216 (2023) 112411. https://doi.org/10.1016/j.vacuum.2023.112411.
[1]
T.F. Allard, G. Weick, Multiple polaritonic edge states in a Su-Schrieffer-Heeger chain strongly coupled to a multimode cavity, Physical Review B 108 (2023) 245417. https://doi.org/10.1103/PhysRevB.108.245417.
[1]
M. Bowen, Atom-level electronic physicists are needed to develop practical engines with a quantum advantage, NPJ Quantum Information 9 (2023) 1–3. https://doi.org/10.1038/s41534-023-00692-x.
[1]
M. Cavallo, E. Bossavit, S. Matzen, T. Maroutian, R. Alchaar, T.H. Dang, A. Khalili, C. Dabard, H. Zhang, Y. Prado, C. Abadie, J.K. Utterback, J.F. Dayen, M.G.G. Silly, P. Dudin, J. Avila, E. Lhuillier, D. Pierucci, Coupling Ferroelectric to colloidal Nanocrystals as a Generic Strategy to Engineer the Carrier Density Landscape, Advanced Functional Materials (2023) 2300846. https://doi.org/10.1002/adfm.202300846.
[1]
M. Cavallo, A. Ram, S. Pandey, T. Maroutian, E. Bossavit, N. Ledos, A. Khalili, H. Zhang, Y. Prado, D.L. Nguyen, T.H. Dang, H. Majjad, J. Biscaras, J. Avila, J.F. Dayen, E. Lhuillier, D. Pierucci, Using wafer scale ferroelectric domains of LiNbO3 to form permanent planar p-n junction in narrow band gap nanocrystals, Applied Physics Letters 123 (2023) 253505. https://doi.org/10.1063/5.0183277.
[1]
X. Chen, Z.-Q. Chen, L. Huang, C. Grebogi, Y.-C. Lai, Many-body spectral statistics of relativistic quantum billiard systems, Physical Review Research 5 (2023) 013050. https://doi.org/10.1103/PhysRevResearch.5.013050.
[1]
X. Chen, G. Weick, D. Weinmann, R.A. Jalabert, Scanning gate microscopy in graphene nanostructures, Physical Review B 107 (2023) 085420. https://doi.org/10.1103/PhysRevB.107.085420.
[1]
M. d’Aquino, R. Hertel, Micromagnetic frequency-domain simulation methods for magnonic systems, Journal of Applied Physics 133 (2023) 033902. https://doi.org/10.1063/5.0131922.
[1]
M. d’Aquino, S. Perna, M. Pancaldi, R. Hertel, S. Bonetti, C. Serpico, Micromagnetic study of inertial spin waves in ferromagnetic nanodots, Physical Review B 107 (2023) 144412. https://doi.org/10.1103/PhysRevB.107.144412.
[1]
V. Desbuis, D. Lacour, C. Tiusan, W. Weber, M. Hehn, sp- and d-band effects on secondary low-energy electron generation, Physical Review B 108 (2023) 214424. https://doi.org/10.1103/PhysRevB.108.214424.
[1]
F.Z. Gadouche, A. Kabir, S. Siouane, C. Sedrati, A. Bouabellou, G. Schmerber, Effect of the Substitution of Barium by Calcium on the Opto-Electronic Properties of Barium tin Oxide, Transactions on Electrical and Electronic Materials Early access (2023). https://doi.org/10.1007/s42341-023-00494-0.
[1]
R. Gumeniuk, V. Levytskyi, B. Kundys, A. Leithe-Jasper, Yb3Rh4Sn13: Two-gap superconductor with a complex Fermi surface, Physical Review B 108 (2023) 214515. https://doi.org/10.1103/PhysRevB.108.214515.
[1]
K. Hoeflich, G. Hobler, F.I. Allen, T. Wirtz, G. Rius, L. McElwee-White, A.V. Krasheninnikov, M. Schmidt, I. Utke, N. Klingner, M. Osenberg, R. Cordoba, F. Djurabekova, I. Manke, P. Moll, M. Manoccio, J.M. De Teresa, L. Bischoff, J. Michler, O. De Castro, A. Delobbe, P. Dunne, O.V. Dobrovolskiy, N. Frese, A. Goelzhaeuser, P. Mazarov, D. Koelle, W. Moeller, F. Perez-Murano, P. Philipp, F. Vollnhals, G. Hlawacek, Roadmap for focused ion beam technologies, Applied Physics Reviews 10 (2023) 041311. https://doi.org/10.1063/5.0162597.
[1]
V. Iurchuk, J. Bran, M. Acosta, B. Kundys, A strain-controlled magnetostrictive pseudo spin valve, Applied Physics Letters 122 (2023) 072404. https://doi.org/10.1063/5.0120426.
[1]
V. Kapustianyk, U. Mostovoi, S. Semak, Y. Eliyashevskyy, Effects of Annealing and Domain Structure on the Photovoltaic Response in Pb[(Mg1/3Nb2/3)0.70Ti0.30]O3 Single Crystal, Physica Status Solidi B-Basic Solid State Physics early access (2023) 2300372. https://doi.org/10.1002/pssb.202300372.
[1]
G. Kremer, A. Mahmoudi, A. M’Foukh, M. Bouaziz, M. Rahimi, M.L. Della Rocca, P. Le Fevre, J.-F. Dayen, F. Bertran, S. Matzen, M. Pala, J. Chaste, F. Oehler, A. Ouerghi, Quantum Confinement and Electronic Structure at the Surface of van der Waals Ferroelectric & alpha; -In2Se3, ACS Nano 17 (2023) 18924–18931. https://doi.org/10.1021/acsnano.3c04186.
[1]
J. Kurian, A. Joseph, S. Cherifi-Hertel, C. Fowley, G. Hlawacek, P. Dunne, M. Romeo, G. Atcheson, J.M.D. Coey, B. Doudin, Deterministic multi-level spin orbit torque switching using focused He+ ion beam irradiation, Applied Physics Letters 122 (2023) 032402. https://doi.org/10.1063/5.0131188.
[1]
N.G. Leumer, On symmetric Tetranacci polynomials in mathematics and physics, Journal of Physics A-Mathematical and Theoretical 56 (2023) 435202. https://doi.org/10.1088/1751-8121/acfbcd.
[1]
L.E.P. Lopez, A. Roslawska, F. Scheurer, S. Berciaud, G. Schull, Tip-induced excitonic luminescence nanoscopy of an atomically resolved van der Waals heterostructure., Nature Materials 22 (2023) 482–488. https://doi.org/10.1038/s41563-023-01494-4.
[1]
G. Magnifouet, M. Vallet, E. Meslin, M. Walls, C. Bouillet, J. Arabski, V. Pierron-Bohnes, Strains in Fe/Cr/Fe trilayers and (Fe/Cr)5/Fe multilayers epitaxied on MgO and MgO/SrTiO3, Thin Solid Films 780 (2023) 139949. https://doi.org/https://doi.org/10.1016/j.tsf.2023.139949.
[1]
K. Maity, J.-F. Dayen, B. Doudin, R. Gumeniuk, B. Kundys, Single Wavelength Operating Neuromorphic Device Based on a Graphene-Ferroelectric Transistor., ACS Applied Materials & Interfaces 15 (2023) 55948–55956. https://doi.org/10.1021/acsami.3c10010.
[1]
K. Maity, J.-F. Dayen, M. Palluel, N. Daro, G. Chastanet, B. Kundys, B. Doudin, Elucidating the effect of spin crossover materials on graphene sensing devices, Applied Physics Letters 123 (2023) 163503. https://doi.org/10.1063/5.0163784.
[1]
D. Markó, R. Cheenikundil, J. Bauer, K. Lenz, W.-C. Chuang, K.-W. Lin, J.-C. Wu, M. d’Aquino, R. Hertel, D.S. Schmool, Interpretation of Spin-Wave Modes in \mathrmCo/\mathrmAg Nanodot Arrays Probed by Broadband Ferromagnetic Resonance, Physical Review Applied 20 (2023) 024059. https://doi.org/10.1103/PhysRevApplied.20.024059.
[1]
K.A. Oukaci, D. Stoeffler, M. Hehn, M. Grassi, B. Sarpi, M. Bailleul, Y. Henry, S. Petit, F. Montaigne, R. Belkhou, D. Lacour, Oscillatory buckling reversal of a weak stripe magnetic texture, Materials Research Letters 11 (2023) 789–795. https://doi.org/10.1080/21663831.2023.2238010.
[1]
S. Pandey, S. Hettler, R. Arenal, C. Bouillet, A.R. Moghe, S. Berciaud, J. Robert, J.-F. Dayen, D. Halley, Room-temperature anomalous Hall effect in graphene in interfacial magnetic proximity to EuO grown by topotactic reduction, Physical Review B 108 (2023) 144423. https://doi.org/10.1103/PhysRevB.108.144423.
[1]
R. Pasquier, M. Alouani, Calculated iron L2,3 x-ray absorption and x-ray magnetic circular dichroism of spin-crossover Fe(phen)2(NCS)2 molecules adsorbed on a Cu(001) surface, Physical Review B 108 (2023) 094423. https://doi.org/10.1103/PhysRevB.108.094423.
[1]
G.J. Percebois, A. Lacerda-Santos, B. Brun, B. Hackens, X. Waintal, D. Weinmann, Reconstructing the potential configuration in a high-mobility semiconductor heterostructure with scanning gate microscopy, SciPost Physics 15 (2023) 242. https://doi.org/10.21468/SciPostPhys.15.6.242.
[1]
S. Pierini, C. Abadie, T.H. Dang, A. Khalili, H. Zhang, M. Cavallo, Y. Prado, B. Gallas, S. Ithurria, S. Sauvage, J.F. Dayen, G. Vincent, E. Lhuillier, Lithium-Ion Glass Gating of HgTe Nanocrystal Film with Designed Light-Matter Coupling., Materials 16 (2023) 2335. https://doi.org/10.3390/ma16062335.
[1]
A. Ram, K. Maity, C. Marchand, A. Mahmoudi, A.R. Kshirsagar, M. Soliman, T. Taniguchi, K. Watanabe, B. Doudin, A. Ouerghi, S. Reichardt, I. O’Connor, J.-F. Dayen, Reconfigurable Multifunctional van der Waals Ferroelectric Devices and Logic Circuits., ACS Nano 17 (2023) 21865–21877. https://doi.org/10.1021/acsnano.3c07952.
[1]
S. Semak, V. Kapustianyk, Y. Eliyashevskyy, O. Bovgyra, M. Kovalenko, U. Mostovoi, B. Doudin, B. Kundys, On the photovoltaic effect asymmetry in ferroelectrics., Journal of Physics. Condensed Matter : An Institute of Physics Journal 35 (2023) 094001. https://doi.org/10.1088/1361-648X/aca579.
[1]
M. Soliman, K. Maity, A. Gloppe, A. Mahmoudi, A. Ouerghi, B. Doudin, B. Kundys, J.-F. Dayen, Photoferroelectric All-van-der-Waals Heterostructure for Multimode Neuromorphic Ferroelectric Transistors., ACS Applied Materials & Interfaces 15 (2023) 15732–15744. https://doi.org/10.1021/acsami.3c00092.
[1]
M. Souissi, G. Schmerber, S. Colis, M. Alruwaili, Study of Zn1-2xNixFexO thin films coated on glass by sol-gel spin-coating method for DMS materials, European Physical Journal Plus 138 (2023). https://doi.org/10.1140/epjp/s13360-023-04312-7.
[1]
L. Temdie, V. Castel, C. Dubs, G. Pradhan, J. Solano, H. Majjad, R. Bernard, Y. Henry, M. Bailleul, V. Vlaminck, High wave vector non-reciprocal spin wave beams, AIP Advances 13 (2023) 025207. https://doi.org/10.1063/9.0000535.
[1]
L. Temdie, V. Castel, T. Reimann, M. Lindner, C. Dubs, G. Pradhan, J. Solano, R. Bernard, H. Majjad, Y. Henry, M. Bailleul, V. Vlaminck, Chiral Excitation of Exchange Spin Waves Using Gold Nanowire Grating, Magnetochemistry 9 (2023) 199. https://doi.org/10.3390/magnetochemistry9080199.
[1]
R. Tuerhong, F. Ngassam, M. Alouani, J.-P. Bucher, When Molecular Dimerization Induces Magnetic Bi-Stability at the Metal-Organic Interface, Advanced Physics Research 2 (2023) 2200005. https://doi.org/10.1002/apxr.202200005.
[1]
V. Vlaminck, L. Temdie, V. Castel, M.B. Jungfleisch, D. Stoeffler, Y. Henry, M. Bailleul, Spin wave diffraction model for perpendicularly magnetized films, Journal of Applied Physics 133 (2023) 053903. https://doi.org/10.1063/5.0128666.
[1]
R. Vollondat, D. Stoeffler, D. Preziosi, S. Roques, A. Slaoui, T. Fix, Tunability of silicon clathrate film properties by controlled guest-occupation of their cages., Journal of Chemical Physics 158 (2023) 164709. https://doi.org/10.1063/5.0143828.
[1]
V.-B. Vu, J.L. Bubendorff, L.D.N. Mouafo, S. Latil, A. Zaarour, J.-F. Dayen, L. Simon, Y.J. Dappe, Graphene/aluminum oxide interfaces for nanoelectronic devices, Electronic Structure 5 (2023) 045005. https://doi.org/10.1088/2516-1075/acff9e.
[1]
C. Weiss, M. Grassi, Y. Roussigne, A. Stashkevich, T. Schefer, J. Robert, M. Bailleul, M. Kostylev, Excitation and reception of magnetostatic surface spin waves in thin conducting ferromagnetic films by coplanar microwave antennas. Part II: Experiment, Journal of Magnetism and Magnetic Materials 565 (2023) 170002. https://doi.org/10.1016/j.jmmm.2022.170002.