about
Controlling the motion of interacting particles: homogeneous systems and binary mixtures.Quantized conductance coincides with state instability and excess noise in tantalum oxide memristors.A novel true random number generator based on a stochastic diffusive memristor.Proton transport and torque generation in rotary biomotors.Memristors with diffusive dynamics as synaptic emulators for neuromorphic computing.Manipulating small particles in mixtures far from equilibrium.Josephson vortex loops in nanostructured Josephson junctions.Geometric stochastic resonance in a double cavity.A superconducting reversible rectifier that controls the motion of magnetic flux quanta.Semiclassical dynamics of electron wave packet states with phase vortices.Interacting particles on a rocked ratchet: rectification by condensation.Stochastic transport of interacting particles in periodically driven ratchets.Controlling transport in mixtures of interacting particles using Brownian motors.Diffusion-controlled generation of a proton-motive force across a biomembrane.Renninger's Gedankenexperiment, the collapse of the wave function in a rigid quantum metamaterial and the reality of the quantum state vector.Ratchet without spatial asymmetry for controlling the motion of magnetic flux quanta using time-asymmetric drivesEffects of lasing in a one-dimensional quantum metamaterialFeedback-controlled adiabatic quantum computationSqueezing as the source of inefficiency in the quantum Otto cycleTwo-qubit parametric amplifier: Large amplification of weak signalsModelling chemical reactions using semiconductor quantum dotsReply to “Comment on ‘Temperature dependence of the Casimir force for lossy bulk media’ ”Terahertz Josephson plasma waves in layered superconductors: spectrum, generation, nonlinear and quantum phenomenaQuantum metamaterials: Electromagnetic waves in Josephson qubit linesExperimentally realizable devices for domain wall motion controlQuantum metamaterial without local controlDistinguishing quantum from classical oscillations in a driven phase qubitQuantum Computing Using Superconducting QubitsMechanisms of Spatiotemporal Selectivity in Cortical Area MT
P50
Q36202935-B71AA5EF-2957-47E9-B25E-574C394E4B83Q36768692-B79A05DC-C611-40A9-8519-25E461F7393CQ42376113-9A1E5208-98EF-4276-9A22-A2A2E85406A5Q46319261-9DA811EA-9DC2-4ECC-952F-680874457006Q46358720-DF8D817B-2BB1-4BF1-8CBF-E926C9114D2BQ49248786-4AE9B68E-22F9-4D1E-A795-2E6659B51271Q49370883-4FEC97C4-A0F7-4C11-963A-A88FD9811C81Q51537570-697F4194-5BB7-400E-9C2F-C6156F14D217Q51798472-C9A80A08-785D-443C-AC2C-667B11E51D66Q51895788-DB37B845-2EC1-413E-BFF0-5D7EF8784A9FQ52409143-C99C7DF2-29FD-448F-9C6D-C23B8631BBF0Q52409164-CDD8B5AA-63B8-46BF-9DBB-275CE5343E7CQ53856296-D31F0CC3-B71C-4AD7-B3CA-EE651F910CD9Q54400674-A15C907C-4450-4840-9AD4-698F14A90E26Q55424889-A39971FC-403F-414F-836D-2A93B0F51163Q56894087-2E839881-A690-4F6B-83AD-CC957C220D78Q58310336-0D967B41-3C47-434F-B24E-D124B0444CA6Q58310430-41C22CFF-60F3-484C-B93F-D1E871199A57Q58310448-8CD99E57-B56F-4A09-AAAE-830C0712EAA5Q58310451-F46A2137-BD38-47B7-86E0-F8CAB6ACCF62Q58310461-17A72358-ED08-4A8A-86C0-826524656AF1Q58310491-3ED4E252-F741-4810-A3CA-6A3F31505B8FQ58310516-8870BECA-F1F5-471F-BA5F-9E3FB4AC85DDQ58310520-E2BAE4F5-EF1E-43B3-9396-8318A01DFDB8Q58310528-858991C1-E95B-4500-AB39-FBBE6BA9E95FQ59423430-6BF1F694-6DD8-43D3-82CE-0F97DC817733Q59423456-313B3E79-8490-4297-A222-A21529E58CD5Q60317951-2303975D-C033-4F13-BE05-CCD071337B93Q64852912-bc941ca4-4af2-80c1-52cc-c1254160e240
P50
description
hulumtues
@sq
researcher
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wetenschapper
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հետազոտող
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name
Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey E Savel'ev
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Sergey E Savelev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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Sergey Savel'ev
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P1053
A-5876-2011
P106
P21
P31
P3829
P496
0000-0003-2771-230X