about
Colloidal superparticles from nanoparticle assembly.Interparticle Forces Underlying Nanoparticle Self-Assemblies.Detection of volatile organic compounds (VOCs) from exhaled breath as noninvasive methods for cancer diagnosis.A new view for nanoparticle assemblies: from crystalline to binary cooperative complementarity.Hierarchical Structures of Bone and Bioinspired Bone Tissue Engineering.Hierarchically Staggered Nanostructure of Mineralized Collagen as a Bone-Grafting Scaffold.The fragmentation of gold nanoparticles induced by small biomolecules.Dual-peak electrogenerated chemiluminescence of carbon dots for iron ions detection.Selective Surface Enhanced Raman Scattering for Quantitative Detection of Lung Cancer Biomarkers in Superparticle@MOF Structure.Seamless Signal Transduction from Three-Dimensional Cultured Cells to a Superoxide Anions Biosensor via In Situ Self-Assembly of Dipeptide Hydrogel.Understanding the Selective Detection of Fe3+ Based on Graphene Quantum Dots as Fluorescent Probes: The Ksp of a Metal Hydroxide-Assisted Mechanism.Silver nanoparticles as matrix for MALDI FTICR MS profiling and imaging of diverse lipids in brain.Self-Assembled Ag-MXA Superclusters with Structure-Dependent Mechanical Properties.Bacterial capture efficiency in fluid bloodstream improved by bendable nanowires.Internanofiber Spacing Adjustment in the Bundled Nanofibers for Sensitive Fluorescence Detection of Volatile Organic Compounds.Ultrasensitive Surface-Enhanced Raman Scattering Sensor of Gaseous Aldehydes as Biomarkers of Lung Cancer on Dendritic Ag Nanocrystals.Sensitive Detection of a Nerve-Agent Simulant through Retightening Internanofiber Binding for Fluorescence Enhancement.Shape-Controlled Synthesis of High-Quality Cu7 S4 Nanocrystals for Efficient Light-Induced Water Evaporation.Large-Scale, Long-Range-Ordered Patterning of Nanocrystals via Capillary-Bridge Manipulation.Dynamically Regulated Ag Nanowire Arrays for Detecting Molecular Information of Substrate-Induced Stretched Cell Growth.Fluorescence Detection of a Broad Class of Explosives with One Zinc(II)-Coordination Nanofiber.Biocompatibility of Magnetic Resonance Imaging Nanoprobes Improved by Transformable Gadolinium Oxide NanocoilArchitectural Design of Self-Assembled Hollow SuperstructuresRapid synthesis of cubic Pt nanoparticles and their use for the preparation of Pt nanoagglomeratesTemplated assembly of gold nanoparticles into microscale tubules and their application in surface-enhanced Raman scatteringSurfactantless synthesis of multiple shapes of gold nanostructures and their shape-dependent SERS spectroscopyA general route to transform normal hydrophilic cloths into superhydrophobic surfacesNanotubes of mixed-valence, transition metal compounds synthesized by solution phase approachThermal annealing of Au nanorod self-assembled nanostructured materials: morphology and optical propertiesA renewable SERS substrate prepared by cyclic depositing and stripping of silver shells on gold nanoparticle microtubesIn situ synthesis and characterization of multiwalled carbon nanotube/Au nanoparticle composite materialsExcitation-intensity-dependent color-tunable dual emissions from manganese-doped CdS/ZnS core/shell nanocrystalsNoncovalent functionalization of multiwalled carbon nanotubes: application in hybrid nanostructuresBinary assembly of colloidal semiconductor nanorods with spherical metal nanoparticlesGas-bubble effects on the formation of colloidal iron oxide nanocrystalsSurface-functionalization-dependent optical properties of II-VI semiconductor nanocrystalsA guard to reduce the accidental oxidation of PbTe nanocrystalsNanomaterial-based gas sensors used for breath diagnosisSelective Capture and in Situ Controllable Detection of d-Glucose in Cerebral SystemsA Metastable Crystalline Phase in Two-Dimensional Metallic Oxide Nanoplates
P50
Q38056054-590752C7-C319-4211-8E26-D470A04AD0E6Q38599203-C4011DF1-B00F-406A-8B5A-B35F39346487Q38671702-85E08AF9-1282-4860-BB0D-C7DCD97E432CQ38774149-66983C28-513C-41A5-B93B-9AC52EFF35BAQ38870699-895042D1-4DFD-4CE2-990B-C322595F087CQ40398006-51E06B92-B68B-4420-BBC0-DA40227845D9Q46348401-39E4A647-F98E-46EB-9918-9401313D16A3Q46890804-036C7996-3946-4989-B69A-E8F46DD8F3C4Q47262928-3C1AAF0A-31FA-4588-8D90-081F306667E1Q47384921-8FA87C36-7E78-4DF6-992C-2B0300CD0439Q47428899-5B6BAC8D-6178-4E77-8ABB-26D2EB01AAF9Q47878191-1C5DED9B-AEA4-40D0-9D4C-B5354DE6D083Q48042991-8310F9C2-D905-46E1-A077-0E184D060449Q48096001-F645B442-F000-424D-93DB-0D7DB94DF0FBQ48136076-2FE59C95-7A74-4C1A-AF57-EC200749900EQ48226779-AF24A511-25F9-4ACF-8945-3472EA69C94EQ48269234-D26E8B1B-BB84-429D-8D6D-AFC7FB7AB16BQ49098198-05FBDF30-E51C-464A-8C34-81C79C6CCDDFQ50069259-3A9A31E2-AE2D-4177-B7BA-1FDF445EE86EQ51164039-E1A1438B-25CF-4D82-9AA6-913AD78D9756Q52866675-6351D576-2C52-414E-9C08-A4CA361BBF72Q57046810-D970EDAF-4A75-464A-8ED1-A2152899FEEEQ57160379-D31831AA-A0A8-474B-B8BA-0729C61240A8Q79199057-50EDC4EE-5CC6-47FC-A610-5FC0EBA139B7Q79946212-CE983A51-0A77-4110-8179-7555035AC68AQ80157263-A478CFC4-9D83-4549-9D06-29DED0D1F944Q80258552-D68C3F20-9897-4BA5-934A-3FDF0B071975Q80701424-29C95D7F-0ACE-4551-811C-D8526587EAB1Q81371243-8054415D-7FF9-4104-BDBB-522A1F52181BQ81403358-1FC668A9-4F60-4F23-8E4F-72EADCF31DFDQ82526754-3BA3BE73-319A-4039-9BD3-547858A03D59Q82621341-6BD9C026-A019-419F-9C0E-3B9D4234698EQ83001393-E41FBD1C-EBFD-4320-9F4E-3C15AEC5E8A4Q83196082-201BC7D8-F421-4C0A-8B5D-D27D2A7D9C60Q84439249-8C6732C2-120C-44D9-98C5-01B9CF03D52FQ85005775-2CF5F44D-693D-4A51-B321-71DB99B9671BQ89271084-CD74EEFE-385E-4AE5-BBCD-4D3341E959EFQ89591388-CCF7D973-17A7-48A6-8C94-2E1E35C46FB0Q90108370-0DD00DFE-156F-4740-A0DC-AA518B94132DQ90657589-64E36C07-F791-4FF8-9088-FE4F373297A5
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Tie Wang
@ast
Tie Wang
@en
Tie Wang
@es
Tie Wang
@sl
type
label
Tie Wang
@ast
Tie Wang
@en
Tie Wang
@es
Tie Wang
@sl
altLabel
T Wang
@en
Tie Wang
@en
Wang T
@en
Wang Tie
@en
prefLabel
Tie Wang
@ast
Tie Wang
@en
Tie Wang
@es
Tie Wang
@sl
P108
P1053
L-5060-2015
P106
P31
P3829
P496
0000-0001-5965-6520
P569
2000-01-01T00:00:00Z