about
Cellular nanotechnology: making biological interfaces smarterPerformance-enhancing methods for Au film over nanosphere surface-enhanced Raman scattering substrate and melamine detection applicationNano- and microstructured materials for in vitro studies of the physiology of vascular cellsWhip spiders (Amblypygi) become water-repellent by a colloidal secretion that self-assembles into hierarchical microstructures.Evaporation-induced assembly of quantum dots into nanoringsAptamer based surface enhanced Raman scattering detection of vasopressin using multilayer nanotube arrays.Osteogenic response of human mesenchymal stem cells to well-defined nanoscale topography in vitro.Nanostructures of designed geometry and functionality enable regulation of cellular signaling processes.Patterning techniques for metal organic frameworks.Sub-10 nm colloidal lithography for circuit-integrated spin-photo-electronic devicesPhysical processes-aided periodic micro/nanostructured arrays by colloidal template technique: fabrication and applications.Enhanced second harmonic generation from Au nanoparticle arrays by femtosecond laser irradiation.Nanotopographical Surfaces for Stem Cell Fate Control: Engineering Mechanobiology from the BottomPartial dark-field microscopy for investigating domain structures of double-layer microsphere filmCritical aspects of substrate nanopatterning for the ordered growth of GaN nanocolumns.Colloidal lithography for fabricating patterned polymer-brush microstructuresFabrication of two-dimensional close-packed shell structure in ceramic thin films.Formation of Carbonized Polystyrene Sphere/hemisphere Shell Arrays by Ion Beam Irradiation and Subsequent Annealing or Chloroform Treatment.Interfacial and volumetric sensitivity of the dry sintering process of polymer colloidal crystals: a thermal transport and photonic bandgap study.Broadband Metallic Planar Microlenses in an Array: the Focusing Coupling Effect.Multiscale conformal pattern transferFabrication of protein dot arrays via particle lithographyPhysical aspects of cell culture substrates: topography, roughness, and elasticity.Emerging chirality in nanoscience.Micro-nanopatterning as tool to study the role of physicochemical properties on cell-surface interactions.Anisotropic gold nanoparticles: synthesis, properties, applications, and toxicity.Enhancement of light output power from LEDs based on monolayer colloidal crystal.Poly (lactic acid)-based biomaterials for orthopaedic regenerative engineering.Fabrication techniques enabling ultrathin nanostructured membranes for separations.Optomagnetically Controlled Microparticles Manufactured with Glancing Angle Deposition.Cucurbit[8]uril-Regulated Nanopatterning of Binary Polymer Brushes via Colloidal TemplatingRational design and synthesis of freestanding photoelectric nanodevices as highly efficient photocatalystsNear-field photochemical and radiation-induced chemical fabrication of nanopatterns of a self-assembled silane monolayer.Colloidal crystals by electrospraying polystyrene nanofluids.Large-scale fabrication of nanodimple arrays for surface-enhanced Raman scattering.Sculpting asymmetric, hollow-core, three-dimensional nanostructures using colloidal particles.Adsorbed emulsion droplets: capping agents for in situ heterogeneous engineering of particle surfaces.Controlling enantiomeric populations in fluctuating Brownian monolayers of chiral colloids.Multi-level micro/nanotexturing by three-dimensionally controlled photofluidization and its use in plasmonic applications.Size-tunable, highly sensitive microelectrode arrays enabled by polymer pen lithography.
P2860
Q27006919-E9AD5765-7C61-42F3-99AB-9D3310FE1CFBQ28539228-19C40411-85F1-4B3D-AD1D-8BF6E5319228Q28817186-79BC185A-F974-49D9-BB28-BC590B092AEDQ28818390-7DAEEA4F-5970-46DC-8FF2-02F09FF2783FQ30473190-01B0F004-BAFC-4CE6-9F45-44E639BF355AQ33637245-B681992B-B6AC-4E71-A8ED-8CEB67EA5CD1Q33689880-DAA5E25D-A688-43D9-B090-0EED55C9BFA5Q33697370-3508F80B-6B08-483F-9D07-6C94B3887D05Q34284861-F0957469-C8E2-4D34-AA48-673ED48F5193Q34568464-C6B8F1F9-847D-4383-809A-5C17A98F24E1Q34583563-6F63E82D-2EB9-459A-87A4-D557401224CCQ34871238-7FC94D07-8049-4E12-ABFD-656DB2C8A097Q35379721-3E295862-AF34-4CCE-A6FF-5077F65A5887Q35591019-42D183AD-960A-4839-A923-4FD08DFF6055Q35690510-4A7AC636-E005-4756-A456-5A6684F2C730Q36072288-CAB3989A-3DC1-436C-9533-CBBBF194EB3FQ36201807-8C82FD96-9D4D-4EC4-98BB-BB02A64F0483Q36350096-9139B3C1-3043-4BE8-8604-AC3768206593Q36399242-69912687-3E5E-424E-93D5-E0D9944C4789Q36626159-F5932209-D728-4394-8856-3526FCAA4424Q37027379-9D275232-3027-4B64-8602-8F4F1AC63140Q37352053-45F0641F-6BFF-4F23-94E2-D82958520F80Q37967641-D159C17D-BE81-4080-BF68-15810D1AB194Q38064723-C9FAE695-18A3-47FA-A736-A90FAC82A87EQ38096336-4616F0F5-CD92-469D-B475-FF935CE8B31EQ38178222-36010EDC-CACC-451E-9183-F126727C270DQ38188510-0FBF74C1-4401-43DD-A91A-CE06367F3E44Q38820059-1F7E4DB6-0896-415A-AA65-2E7E6E68AB4DQ39317747-5150E355-3997-4E05-9C46-4768EE8DEB98Q41151456-C58D3F18-D2CC-4060-95B7-5DC7FBFE9157Q41900120-E3709D55-15EB-4576-A46B-EB1B66BC9BFCQ42412489-B338A557-687C-4BD8-8CE3-147AF16995D8Q42906400-B0D77AF4-37D9-4178-81E7-951678755A9AQ43152064-68ACA0C2-C561-47D0-A804-E9DA096AB58CQ44277462-A91E5E4A-DFB7-4650-81BA-43984C71D1F3Q44876737-2217919C-181D-4850-B787-813E485F9BAEQ44969883-6F71EC99-CC36-4808-9099-21E232212B1BQ46060008-653FDF69-04F7-4498-99E7-01371709F240Q46914690-67236AE1-E07E-481B-BB2B-AF12C159DDB2Q47214192-7B536FEA-DF44-4886-83C4-EDC0277881DA
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
2006年论文
@zh
2006年论文
@zh-cn
name
Nanomachining by colloidal lithography.
@ast
Nanomachining by colloidal lithography.
@en
type
label
Nanomachining by colloidal lithography.
@ast
Nanomachining by colloidal lithography.
@en
prefLabel
Nanomachining by colloidal lithography.
@ast
Nanomachining by colloidal lithography.
@en
P2093
P356
P1433
P1476
Nanomachining by colloidal lithography
@en
P2093
Dae-Geun Choi
Hyung Kyun Yu
Seung-Man Yang
P304
P356
10.1002/SMLL.200500390
P50
P577
2006-04-01T00:00:00Z