about
Strained endotaxial nanostructures with high thermoelectric figure of meritHigh-performance bulk thermoelectrics with all-scale hierarchical architectures.Revisiting AgCrSe2 as a promising thermoelectric material.Enhancing the Figure of Merit of Heavy-Band Thermoelectric Materials Through Hierarchical Phonon Scattering.Structure of the CED-4-CED-9 complex provides insights into programmed cell death in Caenorhabditis elegans.Unit-cell scale mapping of ferroelectricity and tetragonality in epitaxial ultrathin ferroelectric films.Ultrahigh power factor and thermoelectric performance in hole-doped single-crystal SnSe.Liquid-like thermal conduction in intercalated layered crystalline solids.Multiple Converged Conduction Bands in K2Bi8Se13: A Promising Thermoelectric Material with Extremely Low Thermal Conductivity.Understanding Phonon Scattering by Nanoprecipitates in Potassium-Doped Lead Chalcogenides.Unexpected Large Hole Effective Masses in SnSe Revealed by Angle-Resolved Photoemission Spectroscopy.Enhanced thermoelectric properties of SnSe polycrystals via texture control.Understanding Nanostructuring Processes in Thermoelectrics and Their Effects on Lattice Thermal Conductivity.Sol-gel-derived epitaxial nanocomposite thin films with large sharp magnetoelectric effect.N-type Bi-doped SnSe Thermoelectric Nanomaterials Synthesized by a Facile Solution MethodUltrahigh thermoelectric performance in Cu2Se-based hybrid materials with highly dispersed molecular CNTsBiCuSeO oxyselenides: new promising thermoelectric materialsHigh thermoelectric performance in n-type BiAgSeS due to intrinsically low thermal conductivityHigh thermoelectric performance of oxyselenides: intrinsically low thermal conductivity of Ca-doped BiCuSeOTexturation boosts the thermoelectric performance of BiCuSeO oxyselenidesA high thermoelectric figure of merit ZT > 1 in Ba heavily doped BiCuSeO oxyselenidesThe Role of Electron-Phonon Interaction in Heavily Doped Fine-Grained Bulk Silicons as Thermoelectric MaterialsTuning Multiscale Microstructures to Enhance Thermoelectric Performance of n-Type Bismuth-Telluride-Based Solid SolutionsOrigin of the High Performance in GeTe-Based Thermoelectric Materials upon Bi2Te3 DopingElectronic and Magnetic Properties of Ultrathin Au/Pt NanowiresDiverging giant magnetoresistance in ferromagnet-superconductor-ferromagnet trilayers3D charge and 2D phonon transports leading to high out-of-planeZTin n-type SnSe crystalsHigh thermoelectric performance in low-cost SnS0.91Se0.09 crystalsHigh performance thermoelectrics from earth-abundant materials: enhanced figure of merit in PbS by second phase nanostructuresSeeing is believing: weak phonon scattering from nanostructures in alkali metal-doped lead tellurideIon-exchangeable cobalt polysulfide chalcogelNanostructures boost the thermoelectric performance of PbSThermoelectrics with earth abundant elements: high performance p-type PbS nanostructured with SrS and CaSAnomalous electronic transport in dual-nanostructured lead tellurideOn the origin of increased phonon scattering in nanostructured PbTe based thermoelectric materialsStrong phonon scattering by layer structured PbSnS(2) in PbTe based thermoelectric materialsHigh-performance solution-processed amorphous zinc-indium-tin oxide thin-film transistorsIn situ nanostructure generation and evolution within a bulk thermoelectric material to reduce lattice thermal conductivityHigh performance Na-doped PbTe-PbS thermoelectric materials: electronic density of states modification and shape-controlled nanostructuresStrongly nonlinear optical chalcogenide thin films of APSe6 (A=K, Rb) from spin-coating
P50
Q29396061-BB16890F-DDF7-40B5-BF83-93AA90355B19Q34300927-49567985-78B4-4972-93A9-5DF1AC7EAF42Q36103773-8AF07A06-BDCE-4AD0-A28E-58B7F9C7CE2CQ37348936-E51D73BE-9CB6-49E1-9E9B-239F0367E9F2Q39751684-D0266AA5-9CAF-4D76-8AD0-3CD3A116A4FFQ39778813-680EC411-ED3B-4EBB-B0C3-4C30C49083EBQ46553716-ABFB6860-4F70-4D51-B0D7-A759C9D8F180Q48042831-DE01C048-5240-4A37-A7D5-947AE18490B9Q48052386-220B370D-1F87-42C7-81A1-8CAC9CF831C7Q48097069-F6BE5A9D-47CC-4E4E-85CF-7C47CEE2DFC3Q49831145-12CAF044-39C3-4868-AE63-5D820646D5A9Q51101102-C31C6150-1A5D-4A12-85DE-D066AA454607Q51534428-378AB091-E964-4623-901F-F00C5938A108Q53748980-13F27ED2-6ED3-47E6-8C07-CC8127E765DEQ57180957-6813B951-7812-43D8-97CD-1D1DEA5C49E3Q59953635-F50A8182-A51F-4A33-914A-5DA2916AB034Q60457896-B292EF72-7172-460E-801F-1F5C9F30CCA0Q60457910-93968C7A-10F6-4891-B838-AEEE26368210Q60457913-23C4439B-3D65-43C1-A4B4-FE193576A6B8Q60457926-643DC9D9-38F7-47A7-83DA-5569EED6F89EQ60457930-8DD9C3D3-854D-457E-BE0C-08ED253BC9A6Q62675425-66180D1E-08BA-4BD4-9EE9-0DA35081E937Q62675434-0F24DDF5-D1AF-4875-A125-F6C51CC86A0FQ62679283-790D5C0E-7C4C-4CC8-BA55-75325219714FQ62713350-5648EB17-5A48-4BBB-A737-067D15769D0AQ63819895-B6E53FC0-F960-48A4-A6C0-7CC89D47C4D7Q68710718-8FA97EE0-320D-4CE3-B10D-CC249879F9C5Q69497062-E1A3100C-580B-464E-8173-6D708794EBE0Q82726374-5780379B-7F34-4966-B653-7A5EF29A31EBQ82845670-C33C5FA1-9E01-4C03-952E-C9CD4B3BE5AEQ83149775-D2DCE5DC-4627-48C7-9622-6FEDA16A10BDQ83437076-0A705596-0CE8-49BE-932B-42227F1A37C6Q83883961-A998D428-CE1D-47EE-B55B-908F4E23EE2AQ84071846-425685D6-9E4A-490B-85A0-E158B2F3753CQ84356256-3520A162-10A5-4280-B1FE-12A84BEE9940Q84583465-9BBC0C01-7D0E-4617-A761-4A61C7774846Q84598143-F753BF76-44FB-4827-B1C7-AEAE814D7558Q84711178-799C4327-B805-42FB-B674-FFAE63C1A8D2Q84915411-FAD395FC-DBFA-4F79-85E6-3EB70B85A65AQ84970360-32E5B844-8D0D-4262-89AE-AC8185D9FF75
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Jiaqing He
@ast
Jiaqing He
@en
Jiaqing He
@es
Jiaqing He
@nl
type
label
Jiaqing He
@ast
Jiaqing He
@en
Jiaqing He
@es
Jiaqing He
@nl
prefLabel
Jiaqing He
@ast
Jiaqing He
@en
Jiaqing He
@es
Jiaqing He
@nl
P106
P31
P496
0000-0003-3954-6003