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Does the solid-liquid crystal phase transition provoke the spin-state change in spin-crossover metallomesogens?Rapid cooling experiments and use of an anionic nuclear probe to sense the spin transition of the 1D coordination polymers [Fe(NH2trz)3]SnF6n x H2O (NH2trz=4-amino-1,2,4-triazole).Electronic and magnetic phase diagram of beta-Fe(1.01)Se with superconductivity at 36.7 K under pressure.dsRNA-functionalized multifunctional gamma-Fe2O3 nanocrystals: a tool for targeting cell surface receptors.Pressure-induced hysteresis in the high spin [Formula: see text] low spin transition in bis(2,4-bis(pyridin-2-yl)thiazole) iron(II) tetrafluoroborate.Five-coordinate complexes [FeX(depe)(2)]BPh(4), X = Cl, Br: electronic structure and spin-forbidden reaction with N(2).A spin transition molecular material with a wide bistability domain.Supramolecular spintronic devices: spin transitions and magnetostructural correlations in [Fe4IIL4]8+ [2x2]-grid-type complexes.Novel iron(II) microporous spin-crossover coordination polymers with enhanced pore size.Thermal- and light-induced spin crossover in novel 2D Fe(II) metalorganic frameworks {Fe(4-PhPy)(2)[M(II)(CN)(x)](y)}.sH(2)O: spectroscopic, structural, and magnetic studies.Heusler compounds as ternary intermetallic nanoparticles: Co2FeGaIn situ— High Temperature Mössbauer Spectroscopy of Iron Nitrides and NitridoferratesSuperconductivity and magnetism in Rb0.8Fe1.6Se2under pressurePhase separation in superconducting and antiferromagneticRb0.8Fe1.6Se2probed by Mössbauer spectroscopyHyperfine magnetic field on iron atoms and Co–Fe disordering in Co2FeSiOff-stoichiometry in Co2FeSi thin films sputtered from stoichiometric targets revealed by nuclear magnetic resonancePressure Effect Studies on the Spin-Transition Behavior of a Dinuclear Iron(II) CompoundEffect of pressure and light on the spin transition behavior of the dinuclear iron(II) compound [FeII2(PMAT)2](BF4)4⋅DMFEffect of pressure on superconductivity in NaAlSiPressure-restored superconductivity in Cu-substituted FeSeThe effect of Fe doping on superconductivity in ZrRuPA Heteroleptic Push-Pull Substituted Iron(II) Bis(tridentate) Complex with Low-Energy Charge-Transfer States55Mn NMR study of quaternary half-metallic ferromagnetic Co2Mn1−xFexSi Heusler compoundsMagnetic phase transitions and iron valence in the double perovskite Sr 2 FeOsO 6Lattice Instability and Competing Spin Structures in the Double Perovskite InsulatorSr2FeOsO6Phase Separation in RbxFe2−ySe2 Probed by Non-stoichiometry and Cu DopingStructure and electrical resistivity of mixed-valent EuNi2P2at high pressureElectrical and Optical Properties of Sb-Doped BaSnO3Exchange-spring like magnetic behavior of the tetragonal Heusler compound Mn2FeGa as a candidate for spin-transfer torqueIron-based Heusler compounds Fe2YZ: Comparison with theoretical predictions of the crystal structure and magnetic propertiesElectroless synthesis of lepidocrocite (γ-FeOOH) nanotubes in ion track etched polycarbonate templatesResolving the phase structure of nonstoichiometric Co2FeGa Heusler nanoparticlesStructural and magnetic properties of Fe2CoGa Heusler nanoparticlesElectronic, magnetic, and structural properties of the ferrimagnet Mn2CoSnDensity of phonon states in superconducting FeSe as a function of temperature and pressureMagnetic polyorganosiloxane core–shell nanoparticles: Synthesis, characterization and magnetic fractionationProbing the Size Effect of Co2FeGa-SiO2@C Nanocomposite Particles Prepared by a Chemical ApproachElectronic structure, magnetic properties and order–disorder phenomena in Co2Mn1−xFexAlExtreme sensitivity of superconductivity to stoichiometry inFe1+δSeMagnetic properties of GdPdSb and GdNiSb studied by 155Gd-Mössbauer spectroscopy
P50
Q31142244-0F5E1DF7-3844-497E-95E8-F6C4B38A36B9Q31149070-C0D69A0B-A478-412F-9097-0F0D48CFC8E9Q34986748-2E496CD4-6AD9-451C-A6ED-60AF78A7135BQ39982122-196EEED5-3657-4D40-B1D0-9BB2DBD06750Q42728383-8D5C6758-EB29-442E-BD39-E94C791E4917Q44038314-24D37685-543D-4378-A555-D826BB16B4D5Q44254187-6339F9DB-46C7-4C75-BD51-BBE02C612AB6Q44591908-CC1DAA08-6784-4A2D-9303-AD93C5894B54Q45083641-CB314B6B-3B50-445B-8B4B-9132A0221427Q46000519-77BA56AD-E7F6-4348-A35A-93754B48D196Q57867820-A610E4D5-1B6F-4AB5-908E-80C83B04A6C1Q57889645-D4C28F37-C9D2-4E94-B9A9-C537778717E4Q59253094-0398E95E-8C56-4901-81AD-BD59F782C3E9Q59253153-3217036A-1543-4B9B-AB22-1942DC1F7C5EQ59657774-B1F56AA5-6EA0-4EE1-B752-85008E9384E2Q59657786-681EA800-8C7C-45F0-941C-86864C2166F7Q60493123-AE752A33-C39C-4A51-A12F-17E3ECDCC7CFQ60493165-2BD5BCF1-0358-4EAC-A490-8669B75AA827Q61313746-1B6BA3AC-61BA-4DD6-82BB-22931DCD4F98Q61314024-0B3B651F-70E3-4ABC-B26A-1BF53D6A3D7BQ61314025-3B21E6AB-7AEE-4EE2-8ECF-5A0370B8BD84Q61729767-2F0C6D41-F747-4246-9C89-D2FF910521C4Q62382869-BC69F9ED-E653-4A38-8641-E9346F38147AQ62383846-AE907AD1-D911-4EC5-965E-8E005D6688C3Q62383847-9C4E0D37-5EF3-4239-96CA-D2E6F8909404Q62642021-8F96B137-2C19-4198-A2DF-CFFBEC529249Q62642087-BA3081A3-7E0C-4F78-834F-9606B7C96F6CQ62642099-F308F54C-69C0-4639-9CE9-DA0DBDA4FE4DQ62642106-E97B7DE8-C2AB-4113-867C-EE5045DEE0CCQ62642118-D9F5D463-1B7A-4228-8CAC-05D0578108A8Q62642171-07DB8022-7286-4B3D-8EDE-798211016002Q62642192-E4162355-EB39-469D-9CAA-185EEF0B182BQ62642197-0423FB88-B6C7-42A6-8D36-99F0A9A6542DQ62642225-C3A1ADF0-172F-4A2F-8F4C-CB1CB8B2DDF4Q62642265-45097C49-1AE0-411F-8DB0-654A3610961EQ62642282-78E9BBBC-3C06-4CAB-80B4-625945BFC90BQ62642291-8329F8E0-E4A8-4311-9B62-884922ADB068Q62642316-92B2873B-06CA-4322-AB0C-4B02AD1A663BQ62642320-E6AF525B-C915-42BD-8CC8-0AC7C633B03CQ62642328-82280011-9BCA-42A7-B4FB-CEBC726EC135
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Vadim Ksenofontov
@ast
Vadim Ksenofontov
@en
Vadim Ksenofontov
@es
Vadim Ksenofontov
@nl
type
label
Vadim Ksenofontov
@ast
Vadim Ksenofontov
@en
Vadim Ksenofontov
@es
Vadim Ksenofontov
@nl
prefLabel
Vadim Ksenofontov
@ast
Vadim Ksenofontov
@en
Vadim Ksenofontov
@es
Vadim Ksenofontov
@nl
P106
P1153
7004368861
P21
P31
P496
0000-0002-1420-1124