Parametric pumping at finite frequencyAb initio modeling of quantum transport properties of molecular electronic devicesPiezoelectric scattering limited mobility of hybrid organic-inorganic perovskites CH3NH3PbI3Wafer-level photocatalytic water splitting on GaN nanowire arrays grown by molecular beam epitaxy.Continuously tunable electronic structure of transition metal dichalcogenides superlattices.Quantum Transport in Gated Dangling-Bond Atomic Wires.Conductivity of an atomically defined metallic interface.Composition dependent band offsets of ZnO and its ternary alloys.A proposal of a spin cell using light on magnetic tunneling junctions.One-step overall water splitting under visible light using multiband InGaN/GaN nanowire heterostructures.Helical states of topological insulator Bi₂Se₃.Conduction pathway of pi-stacked ethylbenzene molecular wires on Si(100).Impact of edge states on device performance of phosphorene heterojunction tunneling field effect transistors.h-BN/graphene van der Waals vertical heterostructure: a fully spin-polarized photocurrent generator.AlN/h-BN Heterostructures for Mg Dopant-Free Deep Ultraviolet Photonics.Negative differential resistance in GeSi core-shell transport junctions: the role of local sp(2) hybridization.Atomic-Scale Origin of Long-Term Stability and High Performance of p-GaN Nanowire Arrays for Photocatalytic Overall Pure Water Splitting.Nonequilibrium spin injection in monolayer black phosphorus.Multiple pathways of dissociative attachment: CH3Br on Si(100)-2×1.Photogalvanic effect in monolayer black phosphorus.Ab initio simulation of magnetic tunnel junctions.Nonlinear spin current and magnetoresistance of molecular tunnel junctions.Dynamical conductance of model DNA sequences.First principles modeling of tunnel magnetoresistance of Fe/MgO/Fe trilayers.Graphene spintronics: the role of ferromagnetic electrodes.Transient dynamics of magnetic Co-graphene systems.Electric control of spin in monolayer WSe₂ field effect transistors.Giant tunnel magneto-resistance in graphene based molecular tunneling junction.A photochemical diode artificial photosynthesis system for unassisted high efficiency overall pure water splitting.Resonance states of open quantum dots.Two-Dimensional Photogalvanic Spin-BatteryImpurity-limited quantum transport variability in magnetic tunnel junctionsBand offset of GaAs/AlxGa1−xAs heterojunctions from atomistic first principlesElectronic structure of III-V zinc-blende semiconductors from first principlesStructure and dielectric properties of amorphous high-κoxides: HfO2, ZrO2, and their alloysMolecular Spintronics: Destructive Quantum Interference Controlled by a GateAtomic disorder scattering in emerging transistors by parameter-free first principle modelingFirst Principles Simulations of Nanoscale Silicon Devices With Uniaxial StrainGallium nitride nanowire as a linker of molybdenum sulfides and silicon for photoelectrocatalytic water splittingQuantum description of transport phenomena: Recent progress
P50
Q21708463-F3401BEA-DE6A-4E18-9DA9-6806BC8E1BFDQ27350176-CA09BAE1-1B8D-4756-8714-5E32E3D44E01Q30364117-8D4CDEEE-19A8-412D-993E-B0436C3E4869Q34184764-C18D4DD0-EC66-4405-B3EF-8651171253DBQ35079919-A225F619-17BC-4F17-B8D1-DC504B9526B3Q36245712-B4073EB1-1305-4778-A58F-F2645B429F61Q36436970-BB8B9215-B467-4E43-A46E-777BDB128070Q37612638-74E58C26-717A-4CD0-916F-A6711522998DQ39307825-9F55B20E-9765-459A-82F3-F85C6F789767Q39365000-B146C9B4-AD3D-4A27-9AED-C14097751852Q45003913-E110035E-90E4-4941-8F13-CC3261C3A50BQ45928784-4E070AA8-8A1A-4B55-A183-3D33985DB9DCQ48762391-610AEE38-B7E9-42D9-848C-ABE4A0D00671Q50053873-207AF07F-944B-42D5-B913-8856B162C447Q50889288-28519186-CEC4-45B9-8693-E9C335EB56C5Q51190634-A3B03228-5E25-44E8-98B8-45E5A197D721Q51232177-729D587C-A09D-4182-839F-883AE9E69A0FQ51603718-AA0AE744-FEB7-4EC4-835F-6650E4564505Q51607365-4360E835-98A4-467F-9DBE-C2A34B89FC0FQ51678131-39474817-7853-4C5D-A6BE-E3756C01C282Q51902730-0180040C-92D3-4C74-9E36-D0F887F8ECDBQ53004198-D4ABA238-2CB4-4944-B96B-C5E164A4A976Q53012972-BA46E523-C659-4364-B1E4-626FDCCF0504Q53014447-08AAB5E7-3A80-41EC-B73E-BFC350C312D4Q53077888-3CAE1FF7-E2EF-4A79-ABA3-F8739A3F4F7CQ53172346-5F58B3B4-6274-463A-9522-3C13F355E434Q53423046-A201A92A-3BD6-47AF-B9AE-9A8CC5AE5AE2Q53800809-DF7BC842-5592-4966-860A-3A03A71FD63FQ53820731-A1D39212-19E5-4713-B786-40293E082E79Q53986186-C3AD2869-B951-4FAD-B98B-8145F4456F47Q57525931-210F448D-896B-4D25-AE3B-CF3B4C7F44E0Q57525934-AEE8F9E2-1A55-451D-B223-7D49B78145E4Q57525947-FE418DB5-6DDA-4297-8CD0-03566B326371Q57525948-B33397D7-CF64-42A1-9BF3-ABAB794C10BBQ57525950-090CE963-6EF0-4C59-8D19-D3F6E1F271B4Q58180914-1DCA7105-1CCF-4083-B424-59711EA3AE4EQ58215502-7AA6E371-5F54-471D-8E86-ECB11FCCE6B7Q58215537-C98A695F-60B0-489D-80EE-D64A84DF4894Q58705187-484B3E5F-3535-4F8C-9DFA-5EAA3E92B4C8Q59439244-786AC5EE-6547-42D7-BE17-72DF4A70FF1F
P50
description
chinesisch-kanadischer theoretischer Festkörperphysiker
@de
condensed matter physicist at McGill University in Montreal, Canada
@en
natuurkundige
@nl
name
Hong Guo
@ast
Hong Guo
@de
Hong Guo
@en
Hong Guo
@es
Hong Guo
@nl
type
label
Hong Guo
@ast
Hong Guo
@de
Hong Guo
@en
Hong Guo
@es
Hong Guo
@nl
prefLabel
Hong Guo
@ast
Hong Guo
@de
Hong Guo
@en
Hong Guo
@es
Hong Guo
@nl
P106
P166
P21
P31
P496
0000-0003-2127-7968
P569
1950-01-01T00:00:00Z