about
Ultralight, Strong, Three-Dimensional SiC Structures.Novel nanoscale architectures: coated nanotubes and other nanowires.From graphene to silicon carbide: ultrathin silicon carbide flakes.Recent Advances on Carbon Nanotubes and Graphene Reinforced Ceramics Nanocomposites.Metal-organic-frameworks derived cobalt embedded in various carbon structures as bifunctional electrocatalysts for oxygen reduction and evolution reactionsA generic method to synthesise graphitic carbon coated nanoparticles in large scale and their derivative polymer nanocomposites.Tribological performance of Graphene/Carbon nanotube hybrid reinforced Al2O3 compositesBundled tungsten oxide nanowires under thermal processing.Adsorption thermodynamic, kinetic and desorption studies of Pb2+ on carbon nanotubes.Multi-walled carbon/IF-WS2 nanoparticles with improved thermal properties.High-yield bamboo-shaped carbon nanotubes from cresol for electrochemical application.Self-lubricating Al-WS2 composites for efficient and greener tribological parts.How the Toughest Inorganic Fullerene Cages Absorb Shockwave Pressures in a Protective Nanocomposite: Experimental Evidence from Two In Situ Investigations.Ce-Doped bundled ultrafine diameter tungsten oxide nanowires with enhanced electrochromic performance.Efficient synthesis of tungsten oxide hydrate-based nanocomposites for applications in bifunctional electrochromic-energy storage devices.Cobalt sulfide/N,S codoped porous carbon core-shell nanocomposites as superior bifunctional electrocatalysts for oxygen reduction and evolution reactions.Ultra-toughened nylon 12 nanocomposites reinforced with IF-WS2.In-plane large single-walled carbon nanotube films: in situ synthesis and field-emission properties.Growth and characterization of iron oxide nanorods/nanobelts prepared by a simple iron-water reaction.Ideal three-dimensional electrode structures for electrochemical energy storage.Novel route to WOx nanorods and WS2 nanotubes from WS2 inorganic fullerenes.Patterned growth of tungsten oxide and tungsten oxynitride nanorods from Au-coated W foil.Shock-absorbing and failure mechanisms of WS2 and MoS2 nanoparticles with fullerene-like structures under shock wave pressure.Hydrothermal growth mechanism of α-Fe₂O₃ nanorods derived by near in situ analysis.In situ investigations of the phase change behaviour of tungsten oxide nanostructures.Preparation of porous alumina–carbon nanotube composites via direct growth of carbon nanotubesFe-Assisted Synthesis of Si NanowiresLarge-Scale Production of NbS2 Nanowires and Their Performance in Electronic Field EmissionMorphology, Crystallinity and Thermal Properties of Polyamide 66/Polyoxometalate Nanocomposites Synthesised Via an in situ Sol/Gel ProcessProspects for the incorporation of cobalt into α-Fe2O3 nanorods during hydrothermal synthesisTuneable magnetic properties of hydrothermally synthesised core/shell CoFe2O4/NiFe2O4 and NiFe2O4/CoFe2O4 nanoparticlesA highly efficient and versatile carbon nanotube/ceramic composite filterCarbon nanofibres produced from electrospun cellulose nanofibresPreparation and carbon dioxide uptake capacity of N-doped porous carbon materials derived from direct carbonization of zeolitic imidazolate frameworkAtomically homogeneous dispersed ZnO/N-doped nanoporous carbon composites with enhanced CO2 uptake capacities and high efficient organic pollutants removal from waterMicrowave dielectric properties of inorganic fullerene-like tungsten disulfide nanoparticlesMagnesia tuned multi-walled carbon nanotubes–reinforced alumina nanocompositesA cost-effective method for the synthesis of zeolitic imidazolate framework-8 materials from stoichiometric precursors via aqueous ammonia modulation at room temperatureIn situ TEM investigation of β-FeOOH and α-Fe2O3 nanorodsPreparation of 3D graphene-based architectures and their applications in supercapacitors
P50
Q35845378-ECF1EE77-AE6B-4BC7-8EBA-17815F78F3C5Q35888775-E33C2F52-E985-4C55-87F8-0A4775332BEBQ35896135-0FDC7C16-9AF2-4166-AEB4-4E55F2607040Q39202617-70931F6D-0DE6-45E9-8399-F07ED43333D1Q41009735-49208E75-3958-46B8-AC0D-129CD8AD08A8Q41703563-A4DD6C55-8F3F-4E12-9490-3BCBBD2DB8F6Q42411193-0153F9F6-065A-45B0-AB71-0F645B90C664Q42727929-D8641B41-11D9-4D87-9D26-CEC92A8B7BE8Q43319203-CE07534A-4658-43AC-B2F5-8E29FA6B91E1Q45407402-C4310373-5A97-49E2-BA35-A07CB330624AQ46553840-222DCEE0-24A4-49CC-AF1E-F87629CE7CFDQ46565177-9CFAA143-2FE4-449A-911D-6243AFBBF823Q47833505-C3667E59-FAF9-43FF-951D-0C987DFE8085Q49723704-F01D8EEB-2BF1-4B22-AE5E-E6A895A6FAA0Q49851103-F58346EA-E920-4095-8080-C36E072FDF08Q50767361-001410C6-0E2A-4147-B088-1DCFFBC8D78AQ51065087-4E1EA385-2508-44AC-9C7B-696A57CF11EEQ51090732-1372EE01-8069-4F57-B0B1-16B3DFE42443Q51090827-ED7B67BF-284B-454E-921F-2182E377544BQ51132670-EBE9F7DD-C09D-4161-B7DA-8F837762144CQ51133414-54EADF6C-4DE0-45F8-A4EF-AE36A9B7D631Q51312586-6C535B9C-F649-47A1-964C-7D657FFE4477Q51321364-4ED2536D-5307-4597-8736-7FB86CCACE03Q53450868-42CED49D-72C7-4E61-A35E-9D74771675C9Q55038923-AFC54A77-F844-40FB-9256-6BD117EBF5B1Q57610928-ED20DA83-0E9A-48AE-9DC6-632596D7F455Q57610940-CD9C4851-ADC4-4C05-994A-AE3784979DAEQ57915630-DB70267C-0C43-4048-BAE1-7E2ACAE58094Q57917042-5C615B25-B979-48C2-9CFA-FFEE81E4CA07Q57923057-8D6D18C9-7B2C-4E0A-A496-3D2578DAE96FQ57923458-8083BDDC-52B5-4A09-8616-18BC35C673DBQ57932567-6798D276-6EEB-4C9E-8898-425BE968B3FBQ57932569-899AD7F8-5B9A-4486-B104-B48E9E5095DEQ57932575-AD0E9BD7-D87C-4128-8724-4DA351A0413AQ57932577-38AE4215-E4FF-4A0F-B9B6-D10A550F840AQ57933548-BA0EBC02-4980-4091-87C9-716ED1493BDFQ57938664-CDC535B2-3AFB-4B17-9BA0-6D449FEF8A40Q57939006-57ECFBA2-1C18-4F71-9D8F-212424F85D24Q57940561-A8638449-35C4-49F2-9F58-D914A92DB1B3Q57940646-B6486C62-BB8C-4523-9B69-C096D40BA3B7
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Yanqiu Zhu
@ast
Yanqiu Zhu
@en
Yanqiu Zhu
@es
Yanqiu Zhu
@sl
type
label
Yanqiu Zhu
@ast
Yanqiu Zhu
@en
Yanqiu Zhu
@es
Yanqiu Zhu
@sl
prefLabel
Yanqiu Zhu
@ast
Yanqiu Zhu
@en
Yanqiu Zhu
@es
Yanqiu Zhu
@sl
P108
P106
P108
P1153
55613813700
P21
P2798
P31
P3835
yan-qiu-zhu
P496
0000-0003-3659-5643