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Giant elastic tunability in strained BiFeO3 near an electrically induced phase transitionBig-data reflection high energy electron diffraction analysis for understanding epitaxial film growth processes.Phases and Interfaces from Real Space Atomically Resolved Data: Physics-Based Deep Data Image Analysis.Surface Control of Epitaxial Manganite Films via Oxygen Pressure.Bias assisted scanning probe microscopy direct write lithography enables local oxygen enrichment of lanthanum cuprates thin films.Higher order harmonic detection for exploring nonlinear interactions with nanoscale resolution.Single-domain multiferroic BiFeO3 filmsBand excitation in scanning probe microscopy: recognition and functional imaging.Solid-state electrochemistry on the nanometer and atomic scales: the scanning probe microscopy approach.The Ehrlich-Schwoebel barrier on an oxide surface: a combined Monte-Carlo and in situ scanning tunneling microscopy approach.Highly mobile ferroelastic domain walls in compositionally graded ferroelectric thin films.Exploring topological defects in epitaxial BiFeO3 thin films.Dimensionality Controlled Octahedral Symmetry-Mismatch and Functionalities in Epitaxial LaCoO₃/SrTiO₃ Heterostructures.Three-State Ferroelastic Switching and Large Electromechanical Responses in PbTiO3 Thin Films.Deep Learning of Atomically Resolved Scanning Transmission Electron Microscopy Images: Chemical Identification and Tracking Local Transformations.Field enhancement of electronic conductance at ferroelectric domain walls.Nanoscale Probing of Elastic-Electronic Response to Vacancy Motion in NiO Nanocrystals.Consistent Integration of Experimental and Ab Initio Data into Effective Physical Models.Knowledge Extraction from Atomically Resolved Images.Ultrafast current imaging by Bayesian inversion.Deterministic arbitrary switching of polarization in a ferroelectric thin film.Electrocatalysis-induced elasticity modulation in a superionic proton conductor probed by band-excitation atomic force microscopy.Nanoscale control of phase variants in strain-engineered BiFeO₃.Machine learning-enabled identification of material phase transitions based on experimental data: Exploring collective dynamics in ferroelectric relaxors.Controlling magnetoelectric coupling by nanoscale phase transformation in strain engineered bismuth ferriteLearning from Imperfections: Predicting Structure and Thermodynamics from Atomic Imaging of FluctuationsCarrier density modulation in a germanium heterostructure by ferroelectric switchingElectrical Control of Multiferroic Orderings in Mixed-Phase BiFeO3 FilmsMachine Detection of Enhanced Electromechanical Energy Conversion in PbZr Ti O Thin FilmsMaterials Science in the AI age: high-throughput library generation, machine learning and a pathway from correlations to the underpinning physicsBuilding and exploring libraries of atomic defects in graphene: Scanning transmission electron and scanning tunneling microscopy studyRevealing ferroelectric switching character using deep recurrent neural networks
P50
Q30395833-B341E8F0-F731-4CB9-80C8-6CBE27E4A7E3Q30856273-F76987B3-3D17-47F1-AB3F-6AE11B32023DQ31121315-CBA26A11-4287-4978-BDE9-32CB9CEB57C8Q35574900-49548FDC-72A3-4F9A-AFE1-DFE4CD904CE9Q35710073-29530BFF-B418-4025-9296-6AA020DB8C34Q37177615-B2CE7531-3BAB-4A5A-8B63-C3708D5A9DB1Q37260947-260CE1CF-EC6F-4BBC-AAE6-6DD8F4E14383Q38201137-07585342-DB9E-4484-AE57-DBFDD35444A6Q38826042-93CE7637-1567-4B9F-BDB6-58082D7F0150Q40406079-1A0DB034-513C-4524-8CC5-BDC2CAFCF9CEQ44205141-6C5E39E1-FB1A-4F11-BCF7-FF8037B1F101Q44511739-A9C74043-4624-46E6-BA49-90B8119ED194Q46136946-2E453117-22F5-48D1-A2A6-4DA43C1C7282Q46222922-3B048DA5-F387-4491-BDD6-13E48C61E1C3Q46245999-8658684F-2204-4D8B-9EC9-59EB23E63AC4Q47141889-B9A2D64F-8CC5-4842-A5B1-D501FFA7A448Q47882482-134CCC31-1808-4A7C-BCD0-041BE0037A4EQ47891913-5E03EE7F-17B2-420A-B008-E5FAEBF9E098Q47913077-61FBE194-8ED8-4D24-8072-E8E1178BCFA4Q48095960-642E2B2E-C8C9-49BF-BD3E-2617AFB4343AQ50780318-4926A2CB-6A6B-4323-A0CE-4B804B5FFE82Q51645166-A21D6418-6A28-47C3-B402-A27CFB1839C0Q53085912-138AAF8C-AE21-4299-9E9B-689B3A2E6852Q55080072-7F8BF133-5A5B-4BE5-9D92-C31E0637F9C2Q58162785-37FB55BA-31E0-4C19-BF16-6AE5F23D5124Q62853726-BE478E5F-152A-4ECF-BDC1-0DA7C4EC2EC7Q62853938-3F215699-FA8E-4AFF-9199-05B9CA2AE08DQ62854485-5B010A51-5689-48E5-8570-72A47759D115Q64124525-21FFC884-A3EC-4957-B062-A61437B41285Q90285011-8DD247F0-5E91-4B62-8711-0A07576FE8C9Q90621303-67B12691-A1AB-4B67-8F45-1050B1569B71Q90883956-5FDA8DA8-7A44-443C-9047-8B0E0761E5FB
P50
description
researcher
@en
wetenschapper
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հետազոտող
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name
Rama K. Vasudevan
@ast
Rama K. Vasudevan
@en
Rama K. Vasudevan
@es
Rama K. Vasudevan
@nl
Rama K. Vasudevan
@sl
type
label
Rama K. Vasudevan
@ast
Rama K. Vasudevan
@en
Rama K. Vasudevan
@es
Rama K. Vasudevan
@nl
Rama K. Vasudevan
@sl
prefLabel
Rama K. Vasudevan
@ast
Rama K. Vasudevan
@en
Rama K. Vasudevan
@es
Rama K. Vasudevan
@nl
Rama K. Vasudevan
@sl
P1053
Q-2530-2015
P106
P1153
37016796500
P31
P3829
P496
0000-0003-4692-8579