about
Laser Lithography of a Tube-in-a-Tube Nanostructure.Double-walled carbon nanotubes: challenges and opportunities.Applications of carbon nanotubes in biomedical studies.Propagative Sidewall Alkylcarboxylation that Induces Red-Shifted Near-IR Photoluminescence in Single-Walled Carbon Nanotubes.Brightening of carbon nanotube photoluminescence through the incorporation of sp3 defects.Continued growth of single-walled carbon nanotubes.Controlled defects in semiconducting carbon nanotubes promote efficient generation and luminescence of trions.Chemical Control and Spectral Fingerprints of Electronic Coupling in Carbon Nanostructures.Photoactuated Pens for Molecular Printing.Photochemical Creation of Fluorescent Quantum Defects in Semiconducting Carbon Nanotube Hosts.Superacid-Surfactant Exchange: Enabling Nondestructive Dispersion of Full-Length Carbon Nanotubes in Water.Optically Triggered Melting of DNA on Individual Semiconducting Carbon Nanotubes.Chirality-Selective Functionalization of Semiconducting Carbon Nanotubes with a Reactivity-Switchable Molecule.Chemical Gating of a Synthetic Tube-in-a-Tube Semiconductor.Achieving ultrahigh concentrations of fluorescent single-walled carbon nanotubes using small-molecule viscosity modifiers.Interfacial mechanics of carbon nanotube@amorphous-Si coaxial nanostructures.Confined propagation of covalent chemical reactions on single-walled carbon nanotubes.Diameter-dependent, progressive alkylcarboxylation of single-walled carbon nanotubes.Outer wall selectively oxidized, water-soluble double-walled carbon nanotubes.Massively Parallel Dip-Pen Nanolithography of Heterogeneous Supported Phospholipid Multilayer PatternsChanneling Excitons to Emissive Defect Sites in Carbon Nanotube Semiconductors beyond the Dilute RegimeDesign of Elastomer-CNT Film Photoactuators for NanolithographySingle-defect spectroscopy in the shortwave infrared.Dynamic gating of infrared radiation in a textileMassively parallel dip-pen nanolithography with 55 000-pen two-dimensional arraysNanoscopically flat open-ended single-walled carbon nanotube substrates for continued growthUltrathin "bed-of-nails" membranes of single-wall carbon nanotubesMacroscopic, neat, single-walled carbon nanotube fibersKinetically controlled, shape-directed assembly of nanorodsAssembly of nanorods into designer superstructures: the role of templating, capillary forces, adhesion, and polymer hydrationAcyclic cucurbit[n]uril molecular containers selectively solubilize single-walled carbon nanotubes in waterGold-Substrate-Enhanced Scanning Electron Microscopy of Functionalized Single-Wall Carbon NanotubesUltrashort Carbon Nanotubes That Fluoresce Brightly in the Near-InfraredHidden Fine Structure of Quantum Defects Revealed by Single Carbon Nanotube Magneto-PhotoluminescencePhotolithographic Patterning of Organic Color-CentersBanning carbon nanotubes would be scientifically unjustified and damaging to innovationFluorescent sp3 Defect-Tailored Carbon Nanotubes Enable NIR-II Single Particle Imaging in Live Brain Slices at Ultra-Low Excitation DosesConcentrated electrolytes stabilize bismuth-potassium batteriesStretchable Transparent Conductive Films from Long Carbon Nanotube MetalsUltrafast Exciton Trapping at sp3 Quantum Defects in Carbon Nanotubes
P50
Q36279772-F3343E3D-B718-43A0-B39F-8C307A560636Q37806094-CA0A7333-B5DC-41C6-843C-2A2DF2CE38D6Q39572674-54730D87-150C-4262-A885-C61F610224A1Q40634606-63A56C46-01A4-4536-83D4-87648532B26FQ43827975-068ADD64-345B-4862-AAE9-BF00D60CFFE7Q46534458-4F2B324F-599D-4F88-A388-590AA11B71DCQ46914181-C2771FA7-ECFB-4294-87BF-8020E8E94121Q47151732-A425932F-23A8-4D66-8923-B06AF2B23825Q47225040-63DE5C8A-C7D0-41B4-85D2-91771ECA4CC7Q47273029-041636FD-6592-441D-8E42-FA8E81D369BEQ47935673-B4179928-1F10-4DA1-9074-6A5380C297A5Q48060053-A34CEB00-309F-4B60-9BF7-BFF04ED37796Q48170708-825C8628-AAA8-4FBF-A531-87D0F0F10F26Q48267508-BBE3F466-D4A3-48D6-A672-6D6A46343047Q52842659-B364048D-B83B-463D-9ADD-892FC25C49D6Q53400181-CFF6FBD0-1364-4E79-9394-90B6F5A64007Q53415724-DE4EB2F3-2584-400D-9ADE-C5EA50AB73EEQ53451514-9F34DA9A-52EF-4F68-A04A-763091350D91Q53478916-F151D88D-AB9A-4399-96BB-0DEC32708E6AQ57355885-9AB66DDF-6DCF-40E6-B645-0C335857C2F4Q57853331-51AFB608-DB21-4886-9E76-40BE37057D35Q64266157-EA914395-6D61-4632-B02D-FD2244FE0B48Q64890454-313A8842-8BF6-4880-B337-07CEE84D330FQ68712082-DCB51A53-B349-4F37-8714-22C6F50B8D28Q79138971-E72E58B1-85A4-4E46-B4B3-D47934E1120DQ79524832-6049A8D5-BC71-49BB-952E-7DA7042CCA23Q80412283-D0AC417A-7329-4E72-A75C-1A83632F538DQ80538284-FB4CC029-C193-404A-BA6E-048B12008643Q80538321-46515E65-272C-4DB0-9952-1E6FDE0A4977Q82366092-65DA576B-B80F-4EF5-9F15-0912512064DAQ83919127-AA2ED5A7-56DC-440C-B6E5-007AAFD722CAQ85944775-06F70098-EC44-4D79-A89D-A6311779EE83Q89061765-1FABDEE7-A874-4ED0-9CEE-CBDA7DBCFE10Q89694568-8E7041F1-0DED-4DFD-95A4-9004531118D8Q89814043-169D8DC4-D535-4A84-9E09-39DDB009CFAFQ90208652-C5E1CE3E-DF64-4011-ACE8-AB709DADF165Q90633618-5577B5A6-44A3-4B20-AF2C-23D756F34875Q90843817-C068EE8E-BA72-41A8-BEC7-74B3D6F33686Q90849954-1747F9A3-0F8B-4BC7-A6A9-E0D48BCECAFCQ90985190-D88F08E0-FD29-4A85-8144-6C672E533FDE
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
researcher
@en
ricercatore
@it
研究者
@zh
name
YuHuang Wang
@ast
YuHuang Wang
@en
YuHuang Wang
@es
YuHuang Wang
@nl
type
label
YuHuang Wang
@ast
YuHuang Wang
@en
YuHuang Wang
@es
YuHuang Wang
@nl
prefLabel
YuHuang Wang
@ast
YuHuang Wang
@en
YuHuang Wang
@es
YuHuang Wang
@nl
P31
P496
0000-0002-5664-1849