1839302
UVN4N32C
2022
surface-science-reports
50
creator
asc
16584
https://www.ipcms.fr/wp-content/plugins/zotpress/
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[1]
T.F. Allard, G. Weick, Disorder-enhanced transport in a chain of lossy dipoles strongly coupled to cavity photons, Physical Review B 106 (2022) 245424. https://doi.org/10.1103/PhysRevB.106.245424.
[1]
G. Avedissian, J. Arabski, J.A. Wytko, J. Weiss, V. Papaefthimiou, G. Schmerber, G. Rogez, E. Beaurepaire, C. Mény, Exchange bias at the organic/ferromagnet interface may not be a spinterface effect, Applied Physics Reviews 9 (2022) 011417. https://doi.org/10.1063/5.0054524.
[1]
W. Belayachi, G. Ferblantier, T. Fix, G. Schmerber, J.-L. Rehspringer, T. Heiser, A. Slaoui, M. Abd-Lefdil, A. Dinia, SnO2 Films Elaborated by Radio Frequency Magnetron Sputtering as Potential Transparent Conducting Oxides Alternative for Organic Solar Cells, ACS Applied Energy Materials 5 (2022) 170–177. https://doi.org/10.1021/acsaem.1c02711.
[1]
C. Blaas-Anselmi, F. Helluin, R. Jalabert, G. Weick, D. Weinmann, Asymmetric power dissipation in electronic transport through a quantum point contact, SciPost Phys. 12 (2022) 105. https://doi.org/10.21468/SciPostPhys.12.3.105.
[1]
S. Bouzida, M. Battas, E.B. Benamar, G. Schmerber, A. Dinia, M. Abd-Lefdil, M. Regragui, Effect of volume of the solution and sulfurization on properties of Cu2ZnSnS4 thin films fabricated by spray assisted chemical vapour deposition method, Materials Research Innovations 26 (2022) 127–133. https://doi.org/10.1080/14328917.2021.1904627.
[1]
R. Cheenikundil, J. Bauer, M. Goharyan, M. d’Aquino, R. Hertel, High-frequency modes in a magnetic buckyball nanoarchitecture, APL Materials 10 (2022) 081106. https://doi.org/10.1063/5.0097695.
[1]
B. Chowrira, L. Kandpal, M. Lamblin, F. Ngassam, C.-A. Kouakou, T. Zafar, D. Mertz, B. Vileno, C. Kieber, G. Versini, B. Gobaut, L. Joly, T. Ferté, E. Monteblanco, A. Bahouka, R. Bernard, S. Mohapatra, H. Prima Garcia, S. Elidrissi, M. Gavara, E. Sternitzky, V. Da Costa, M. Hehn, F. Montaigne, F. Choueikani, P. Ohresser, D. Lacour, W. Weber, S. Boukari, M. Alouani, M. Bowen, Quantum Advantage in a Molecular Spintronic Engine that Harvests Thermal Fluctuation Energy., Advanced Materials Early access (2022) e2206688–e2206688. https://doi.org/10.1002/adma.202206688.
[1]
A.V. Chumak, P. Kabos, M. Wu, C. Abert, C. Adelmann, A.O. Adeyeye, J. Åkerman, F.G. Aliev, A. Anane, A. Awad, C.H. Back, A. Barman, G.E.W. Bauer, M. Becherer, E.N. Beginin, V.A.S.V. Bittencourt, Y.M. Blanter, P. Bortolotti, I. Boventer, D.A. Bozhko, S.A. Bunyaev, J.J. Carmiggelt, R.R. Cheenikundil, F. Ciubotaru, S. Cotofana, G. Csaba, O.V. Dobrovolskiy, C. Dubs, M. Elyasi, K.G. Fripp, H. Fulara, I.A. Golovchanskiy, C. Gonzalez-Ballestero, P. Graczyk, D. Grundler, P. Gruszecki, G. Gubbiotti, K. Guslienko, A. Haldar, S. Hamdioui, R. Hertel, B. Hillebrands, T. Hioki, A. Houshang, C.-M. Hu, H. Huebl, M. Huth, E. Iacocca, M.B. Jungfleisch, G.N. Kakazei, A. Khitun, R. Khymyn, T. Kikkawa, M. Kläui, O. Klein, J.W. Kłos, S. Knauer, S. Koraltan, M. Kostylev, M. Krawczyk, I.N. Krivorotov, V.V. Kruglyak, D. Lachance-Quirion, S. Ladak, R. Lebrun, Y. Li, M. Lindner, R. Macêdo, S. Mayr, G.A. Melkov, S. Mieszczak, Y. Nakamura, H.T. Nembach, A.A. Nikitin, S.A. Nikitov, V. Novosad, J.A. Otálora, Y. Otani, A. Papp, B. Pigeau, P. Pirro, W. Porod, F. Porrati, H. Qin, B. Rana, T. Reimann, F. Riente, O. Romero-Isart, A. Ross, A.V. Sadovnikov, A.R. Safin, E. Saitoh, G. Schmidt, H. Schultheiss, K. Schultheiss, A.A. Serga, S. Sharma, J.M. Shaw, D. Suess, O. Surzhenko, K. Szulc, T. Taniguchi, M. Urbánek, K. Usami, A.B. Ustinov, T. van der Sar, S. van Dijken, V.I. Vasyuchka, R. Verba, S.V. Kusminskiy, Q. Wang, M. Weides, M. Weiler, S. Wintz, S.P. Wolski, X. Zhang, Advances in Magnetics Roadmap on Spin-Wave Computing, IEEE Transactions on Magnetics 58 (2022) 1–72. https://doi.org/10.1109/TMAG.2022.3149664.
[1]
A.A. Dev, P. Dunne, T.M. Hermans, B. Doudin, Fluid Drag Reduction by Magnetic Confinement, Langmuir 38 (2022) 719–726. https://doi.org/10.1021/acs.langmuir.1c02617.
[1]
T.K. Ekanayaka, K.P. Maity, B. Doudin, P.A. Dowben, Dynamics of Spin Crossover Molecular Complexes, Nanomaterials 12 (2022) 1742. https://doi.org/10.3390/nano12101742.
[1]
C. Ferrante, G.D. Battista, L.E.P. López, G. Batignani, E. Lorchat, A. Virga, S. Berciaud, T. Scopigno, Picosecond energy transfer in a transition metal dichalcogenide–graphene heterostructure revealed by transient Raman spectroscopy, Proceedings of the National Academy of Sciences 119 (2022) e2119726119. https://doi.org/10.1073/pnas.2119726119.
[1]
A. Gloppe, M. Onga, R. Hisatomi, A. Imamoglu, Y. Nakamura, Y. Iwasa, K. Usami, Magnon-exciton proximity coupling at a van der Waals heterointerface, Physical Review B 105 (2022) L121403. https://doi.org/10.1103/PhysRevB.105.L121403.
[1]
M. Grassi, M. Geilen, K.A. Oukaci, Y. Henry, D. Lacour, D. Stoeffler, M. Hehn, P. Pirro, M. Bailleul, Higgs and Goldstone spin-wave modes in striped magnetic texture, Physical Review B 105 (2022) 044444. https://doi.org/10.1103/PhysRevB.105.094444.
[1]
M. Guyot, M.-N. Lalloz, J.S. Aguirre-Araque, G. Rogez, C. Costentin, S. Chardon-Noblat, Rhenium Carbonyl Molecular Catalysts for CO2 Electroreduction: Effects on Catalysis of Bipyridine Substituents Mimicking Anchorage Functions to Modify Electrodes, Inorganic Chemistry 61 (2022) 16072–16080. https://doi.org/10.1021/acs.inorgchem.2c02473.
[1]
L. Joly, F. Scheurer, P. Ohresser, B. Kengni-Zanguim, J.-F. Dayen, P. Seneor, B. Dlubak, F. Godel, D. Halley, X-ray magnetic dichroism and tunnel magneto-resistance study of the magnetic phase in epitaxial CrVO x nanoclusters, Journal of Physics-Condensed Matter 34 (2022) 175801. https://doi.org/10.1088/1361-648X/ac4f5e.
[1]
V. Kapustianyk, S. Semak, Y. Chornii, M. Rudko, Manifestation of ferroelastoelectric phase transition in temperature changes of the optical absorption edge in (NH4)(2)CuCl4 center dot 2H(2)O crystal, Phase Transitions 95 (2022) 626–633. https://doi.org/10.1080/01411594.2022.2088372.
[1]
V. Kapustianyk, I. Bolesta, S. Semak, Yu. Eliyashevskyy, U. Mostovoi, O. Kushnir, B. Turko, M. Rudko, Coupling of the surface plasmon resonance with ferroelectricity in “DMAAlS crystal plus silver nanoparticles” composite, Applied Physics A-Materials Science & Processing 128 (2022). https://doi.org/10.1007/s00339-022-06225-1.
[1]
L. Khalil, P.M. Forcella, G. Kremer, F. Bisti, J. Chaste, J.-C. Girard, F. Oehler, M. Pala, J.-F. Dayen, D. Logoteta, M. Goerbig, F. Bertran, P. Le Fevre, E. Lhuillier, J. Rault, D. Pierucci, G. Profeta, A. Ouerghi, alpha-As2Te3 as a platform for the exploration of the electronic band structure of single layer beta-tellurene, Physical Review B 106 (2022) 125152. https://doi.org/10.1103/PhysRevB.106.125152.
[1]
L. Koerber, A. Hempel, A. Otto, R.A. Gallardo, Y. Henry, J. Lindner, A. Kakay, Finite-element dynamic-matrix approach for propagating spin waves: Extension to mono- and multi-layers of arbitrary spacing and thickness, AIP ADVANCES 12 (2022) 115206. https://doi.org/10.1063/5.0107457.
[1]
R. Kozubski, C. Issro, K. Zapala, M. Kozlowski, M. Rennhofer, E. Partyka, V. Pierron-Bohnes, W. Pfeiler, Atomic migration and ordering phenomena in bulk and thin films of FePd and FePt, International Journal of Materials Research 97 (2022) 273–284. https://doi.org/10.3139/ijmr-2006-0044.
[1]
E. Kume, N. Martin, P. Dunne, P. Baroni, L. Noirez, Collective Effects in Ionic Liquid [emim][Tf2N] and Ionic Paramagnetic Nitrate Solutions without Long-Range Structuring., Molecules 27 (2022) 7829. https://doi.org/10.3390/molecules27227829.
[1]
V. Levytskyi, W. Carrillo-Cabrera, L. Akselrud, B. Kundys, A. Leithe-Jasper, R. Gumeniuk, Superconductivity of structurally disordered Y5Ir6Sn18, Dalton Transactions 51 (2022) 10036–10046. https://doi.org/10.1039/d2dt01353c.
[1]
K.P. Maity, A. Patra, N. Tanty, V. Prasad, Magnetic field driven dielectric relaxation in non-magnetic composite medium: A low temperature study, Materials Chemistry and Physics 289 (2022) 126486. https://doi.org/10.1016/j.matchemphys.2022.126486.
[1]
A. Makhort, R. Gumeniuk, J.-F. Dayen, P. Dunne, U. Burkhardt, M. Viret, B. Doudin, B. Kundys, Photovoltaic-Ferroelectric Materials for the Realization of All-Optical Devices, Advanced Optical Materials 10 (2022) 2102353. https://doi.org/10.1002/adom.202102353.
[1]
S. Mohapatra, S. Cherifi-Hertel, S.K. Kuppusamy, G. Schmerber, J. Arabski, B. Gobaut, W. Weber, M. Bowen, V. Da Costa, S. Boukari, Organic ferroelectric croconic acid: a concise survey from bulk single crystals to thin films, Journal of Materials Chemistry C 10 (2022) 8142–8167. https://doi.org/10.1039/D1TC05310H.
[1]
S. Mohapatra, W. Weber, M. Bowen, S. Boukari, V. Da Costa, Toward accurate ferroelectric polarization estimation in nanoscopic systems, Journal of Applied Physics 132 (2022) 134101. https://doi.org/10.1063/5.0102920.
[1]
A.N. Morozovska, E.A. Eliseev, S. Cherifi-Hertel, D.R. Evans, R. Hertel, Electric field control of labyrinth domain structures in core-shell ferroelectric nanoparticles, Physical Review B 106 (2022) 144104. https://doi.org/10.1103/PhysRevB.106.144104.
[1]
F. Omeis, Z. Boubegtiten-Fezoua, A.F.S. Seica, R. Bernard, M.H. Iqbal, N. Javahiraly, R.M.A. Vergauwe, H. Majjad, F. Boulmedais, D. Moss, P. Hellwig, Plasmonic Resonant Nanoantennas Induce Changes in the Shape and the Intensity of Infrared Spectra of Phospholipids, Molecules 27 (2022) 62. https://doi.org/10.3390/molecules27010062.
[1]
R. Pasquier, K. Rassoul, M. Alouani, Inverse spin crossover in fluorinated Fe(1,10-phenanthroline)2(NCS) 2 adsorbed on Cu (001) surface, Computational Condensed Matter 32 (2022) e00735. https://doi.org/10.1016/j.cocom.2022.e00735.
[1]
R.J. Pena Roman, D. Pommier, R. Bretel, L.E.P. Lopez, E. Lorchat, J. Chaste, A. Ouerghi, S. Le Moal, E. Boer-Duchemin, G. Dujardin, A.G. Borisov, L.F. Zagonel, G. Schull, S. Berciaud, E. Le Moal, Electroluminescence of monolayer WS2 in a scanning tunneling microscope: Effect of bias polarity on spectral and angular distribution of emitted light, Physical Review B 106 (2022) 085419. https://doi.org/10.1103/PhysRevB.106.085419.
[1]
R.J. Peña Román, R. Bretel, D. Pommier, L.E. Parra López, E. Lorchat, E. Boer-Duchemin, G. Dujardin, A.G. Borisov, L.F. Zagonel, G. Schull, S. Berciaud, E. Le Moal, Tip-Induced and Electrical Control of the Photoluminescence Yield of Monolayer WS2, Nano Lett. 22 (2022) 9244–9251. https://doi.org/10.1021/acs.nanolett.2c02142.
[1]
G.J. Percebois, D. Weinmann, R.A. Jalabert, G. Weick, Spontaneous orbital magnetization of mesoscopic dipole dimers, Physical Review B 105 (2022) 085405. https://doi.org/10.1103/PhysRevB.105.085405.
[1]
J. Solano, O. Gladii, P. Kuntz, Y. Henry, D. Halley, M. Bailleul, Spin-wave study of magnetic perpendicular surface anisotropy in single crystalline MgO/Fe/MgO films, Physical Review Materials 6 (2022) 124409. https://doi.org/10.1103/PhysRevMaterials.6.124409.
[1]
A. Tarhini, J. Aguirre-Araque, M. Guyot, C. Costentin, G. Rogez, S. Chardon-Noblat, V. Prevot, C. Mousty, Behavior of Iron Tetraphenylsulfonato Porphyrin Intercalated into LDH and LSH as Materials for Electrocatalytic Applications, Electrocatalysis 14 (2022) 111–120. https://doi.org/10.1007/s12678-022-00778-8.
[1]
V. Tokar I., Exact renormalization group equation for lattice Ginzburg-Landau models adapted to the solution in the local potential approximation, Journal of Statistical Mechanics-Theory and Experiment 2022 (2022) 123202. https://doi.org/10.1088/1742-5468/aca0e6.
[1]
X. Weng, M. Hennes, A. Juhin, P. Sainctavit, B. Gobaut, E. Otero, F. Choueikani, P. Ohresser, T. Tran, D. Hrabovsky, D. Demaille, Y. Zheng, F. Vidal, Strain-engineering of magnetic anisotropy in CoxNi1-x-SrTiO3/SrTiO3(001) vertically assembled nanocomposites, Physical Review Materials 6 (2022) 046001. https://doi.org/10.1103/PhysRevMaterials.6.046001.