about
Improving the morphological stability of a polycrystalline tungsten nanowire with a carbon shell.Enhanced Field Emission from Argon Plasma-Treated Ultra-sharp alpha-Fe(2)O(3) Nanoflakes.A cheap and non-destructive approach to increase coverage/loading of hydrophilic hydroxide on hydrophobic carbon for lightweight and high-performance supercapacitorsChemical insights into the roles of nanowire cores on the growth and supercapacitor performances of Ni-Co-O/Ni(OH)₂ core/shell electrodesCobalt monoxide-doped porous graphitic carbon microspheres for supercapacitor applicationLow-contact-resistance graphene devices with nickel-etched-graphene contacts.Light enhanced energy storage ability through a hybrid plasmonic Ag nanowire decorated hydroxide "skin structure".Highly stable new organic-inorganic perovskite (CH₃NH₃)₂PdBr₄: synthesis, structure and physical properties.Remarkable improvement in supercapacitor performance by sulfur introduction during a one-step synthesis of nickel hydroxide.Partial conversion of current collectors into nickel copper oxide electrode materials for high-performance energy storage devices.Influence of Ligands on the Formation of Kesterite Thin Films for Solar Cells: A Comparative Study.(CH3 NH3 )2 PdCl4 : A Compound with Two-Dimensional Organic-Inorganic Layered Perovskite Structure.Co3O4 Nanowire@MnO2 ultrathin nanosheet core/shell arrays: a new class of high-performance pseudocapacitive materials.Localized suppression of longitudinal-optical-phonon-exciton coupling in bent ZnO nanowires.The morphology of Au@MgO nanopeapods.Hierarchical assembly of ZnO nanostructures on SnO(2) backbone nanowires: low-temperature hydrothermal preparation and optical properties.Multifunctional CuO nanowire devices: p-type field effect transistors and CO gas sensors.Direct n- to p-Type Channel Conversion in Monolayer/Few-Layer WS2 Field-Effect Transistors by Atomic Nitrogen Treatment.Study of copper silicide retardation effects on copper diffusion in siliconCellular distribution of GPR14 and the positive inotropic role of urotensin II in the myocardium in adult rat.A High Energy Density Asymmetric Supercapacitor from Nano-architectured Ni(OH)2/Carbon Nanotube ElectrodesFerromagnetism in ZnO Nanowires Derived from Electro-deposition on AAO Template and Subsequent OxidationHighly Stable New Organic-Inorganic Hybrid 3D Perovskite CHNHPdI and 2D Perovskite (CHNH)PdI: DFT Analysis, Synthesis, Structure, Transition Behavior, and Physical PropertiesSimultaneous edge and electronic control of MoS nanosheets through Fe doping for an efficient oxygen evolution reactionLignin-derived interconnected hierarchical porous carbon monolith with large areal/volumetric capacitances for supercapacitorGlucose-assisted reduction achieved transparent p-type cuprous oxide thin film by a solution methodImproved mobility of sol-gel method processed transparent tin sulfide thin filmsCharacterisation of high temperature corrosion products on FeAl intermetallics by XPSDevelopment of ZnO Nanostructured Films via Sodium Chloride Solution and Investigation of Its Growth Mechanism and Optical PropertiesThe characterization and application of p-type semiconducting mesoporous carbon nanofibersRoom-temperature ferromagnetism in ZnO-encapsulated 1.9 nm FePt3 nanoparticle-composite thin films with giant interfacial anisotropyLarge-diameter graphene nanotubes synthesized using Ni nanowire templatesCobalt-mediated crystallographic etching of graphite from defectsEnhancement of bandgap emission of Pt-capped MgZnO films: important role of light extraction versus exciton-plasmon couplingTemperature effect on the binder-free nickel copper oxide nanowires with superior supercapacitor performanceSuperior performance asymmetric supercapacitors based on a directly grown commercial mass 3D Co3O4@Ni(OH)2 core-shell electrodeBoosted electrochemical properties from the surface engineering of ultrathin interlaced Ni(OH)2 nanosheets with Co(OH)2 quantum dot modificationHighly stretchable and transparent films based on celluloseNew Transparent Magnetic Semiconductor NixCu1-xI which Can Perform as Either P-type or N-type and Success in the P-N Homojunction DiodeA New Highly Conductive Direct Gap p-Type Semiconductor La1-xYxCuOS for Dual Applications: Transparent Electronics and Thermoelectricity
P50
Q33558394-1442F3A7-5548-408D-82B1-3968AE426CB1Q33949951-FB6D68AF-6897-4D42-9CC5-9D45145770AEQ36353484-4E30F56F-C364-492A-8744-594A89ED9968Q36560172-230C5FD6-7BC5-485C-AD17-FAD1E208329FQ37226457-201B05AD-E957-4106-99A0-D6FE1E6E0368Q39297156-B045EB83-5CC0-41F7-BE4A-48DB0F43BF15Q47337562-6E23AE21-AD5E-4604-9B75-581766EC5079Q50091210-9E0335E5-5DB5-473A-A931-0AC9573849C8Q50662358-3B43A4A2-6B1F-4BF6-9190-628240B47414Q50961125-39B8D95D-2D0E-44E1-84D7-F2A847826D8CQ51382489-726874F0-7172-4BE6-989F-11F23C4FDB1AQ51568809-503042C3-62DD-4450-9321-B9090C054E00Q51590527-0D39946D-870B-4433-91F4-0B7FB7C6CA7DQ51649604-9D91560F-9722-4960-B3C6-8D150675DA25Q51784023-6C5E95BD-CD38-48AD-87B7-8FDFD80B3A43Q51791376-08086475-C163-4E99-9E52-597B00F7186CQ51833427-9E112670-BA28-4E2D-AF08-3B6D6A334E3BQ52674111-46FF1598-F03A-4DD8-861F-4B58A048B782Q54133032-5BE89021-0ECC-4CFF-AD1A-6768B7F462F1Q54708765-79F94CBF-C634-47AA-9D59-962721CDEB1AQ55920158-3D5DBD20-3B00-4643-99B9-D3F91817C8BDQ56658870-7C47F5FB-5D0C-4D98-A4F7-FC315519D33EQ57029113-C15E1EDA-2D49-462E-9219-4082AB927BC6Q58097590-2FAE6F3D-809E-4AF0-9D2A-F60A15F4C59FQ58173838-77F122B4-5234-45F6-AD6A-E56FB732EBCFQ59906663-E0E7E5AF-D59D-4CD9-B088-1BCA7C2F70EFQ59906668-943CCB3B-2E48-4132-A247-CABE51D36319Q60455903-D1DE3C7B-F93F-4F50-84C8-A6552413B1F2Q62041922-F3C2A7FC-4C20-4E8C-B9D5-6FD46F9F7A4DQ62395896-FC31A815-B2FE-4257-B87A-3E90BC1C2E86Q64110893-AA1E3318-7327-4210-9C9F-8907357E861FQ82203409-9D9079B5-E648-4A5F-A3F8-3DFDE79A0FECQ84008197-5D645BC1-9CEC-44EA-9F27-C69A2078DC7BQ84414714-7281FF33-93EE-4F38-9907-2155499BB96FQ85342240-1AFE5062-E321-4E5A-A208-BF6D28DD250FQ86441253-03F02789-35F0-4EC0-8335-C63E3A26FD24Q88886147-21A50814-6EA1-4BA2-AA01-1B5660C25E99Q91635927-3FE74A42-2786-4781-90AD-43C82ADCE540Q92489683-0C584642-A3DF-402E-9B40-3FE151DE7AC4Q92512000-0BCB3A13-9306-4CC4-8916-7E1DCBE53CBC
P50
description
forsker
@nb
onderzoeker uit Singapore
@nl
researcher
@en
հետազոտող
@hy
name
H. Gong
@ast
H. Gong
@nl
H. Gong
@sl
Hao Gong
@en
Hao Gong
@es
Hao Gong
@nb
Hao Gong
@sq
type
label
H. Gong
@ast
H. Gong
@nl
H. Gong
@sl
Hao Gong
@en
Hao Gong
@es
Hao Gong
@nb
Hao Gong
@sq
altLabel
H. Gong
@en
prefLabel
H. Gong
@ast
H. Gong
@nl
H. Gong
@sl
Hao Gong
@en
Hao Gong
@es
Hao Gong
@nb
Hao Gong
@sq
P106
P27
P31
P496
0000-0002-0410-5147