about
Progression of occupational risk management with advances in nanomaterialsAn electromechanical material testing system for in situ electron microscopy and applications.A method for measuring rotation of a thermal carbon nanomotor using centrifugal effect.Carbon Nanotube Electron Windmills: A Novel Design for NanomotorsMotion of Adsorbed Nano-Particles on Azobenzene Containing Polymer FilmsManipulation of small particles at solid liquid interface: light driven diffusioosmosisMan-made rotary nanomotors: a review of recent developments.Robust rotation of rotor in a thermally driven nanomotorGraphite flake self-retraction response based on potential seeking.Wireless powering of e-swimmersMotion Driven by Strain Gradient Fields.Wettability and Coalescence of Cu Droplets Subjected to Two-Wall Confinement.Extracting subnanometer single shells from ultralong multiwalled carbon nanotubes.RNA nanotechnology: engineering, assembly and applications in detection, gene delivery and therapyEvaluation of the nanotube intrinsic resistance across the tip-carbon nanotube-metal substrate junction by Atomic Force Microscopy.Binomial distribution for quantification of protein subunits in biological nanoassemblies and functional nanomachinesGraphene fibers with predetermined deformation as moisture-triggered actuators and robots.Micromotors with step-motor characteristics by controlled magnetic interactions among assembled componentsElastomeric nanocomposite scaffolds made from poly (glycerol sebacate) chemically crosslinked with carbon nanotubes.New approach to develop ultra-high inhibitory drug using the power function of the stoichiometry of the targeted nanomachine or biocomplex.Rise of the nanomachine: the evolution of a revolution in medicine.Modelling interwall interactions in carbon nanotubes: fundamentals and device applications.Ultra-durable rotary micromotors assembled from nanoentities by electric fields.Strain-dependent twist-stretch elasticity in chiral filaments.Optimal run-and-tumble-based transportation of a Janus particle with active steering.Double-walled carbon nanotubes: challenges and opportunities.The registry index: a quantitative measure of materials' interfacial commensurability.Carbon nanotube and graphene-based bioinspired electrochemical actuators.Recent Progress on Man-Made Inorganic Nanomachines.Horizontally aligned carbon nanotube arrays: growth mechanism, controlled synthesis, characterization, properties and applications.Fuel-Free Synthetic Micro-/Nanomachines.Ab initio study of edge effect on relative motion of walls in carbon nanotubes.Micro/nanomotors towards in vivo application: cell, tissue and biofluid.Solution-processed Ag-doped ZnO nanowires grown on flexible polyester for nanogenerator applications.Plasma-Assisted Synthesis of Carbon Nanotubes.Physicochemically tunable polyfunctionalized RNA square architecture with fluorogenic and ribozymatic properties.Mode Coupling and Nonlinear Resonances of MEMS Arch Resonators for Bandpass Filters.Conditions for escape of a rotor in a rotary nanobearing from short triple-wall nanotubes.Negative differential electrical resistance of a rotational organic nanomotorSelf-assembly of a parallelogram black phosphorus ribbon into a nanotube.
P2860
Q23923401-567E87F1-BDCD-43C1-BFCF-40AB637A217BQ24534779-88FBDEC3-63BC-44DF-9C82-FEE45FCBBEC5Q27345545-D1D60907-6067-433F-B716-D8F7987513BBQ27350345-ABE053DD-609D-4D8E-B60A-F245CF3D112EQ28073166-7643FF71-2A9B-4388-963F-6637603AA234Q28822284-24E7BA88-F656-4832-A3E6-37ED4FE2DD5FQ30356007-20514F23-5627-40B8-B511-A7A9821828E4Q30358882-F5FFF020-6AA2-4901-ABF4-6591619CA66DQ30468590-FB119583-1656-4097-9AB3-3057132A29A0Q30594640-EA20A53E-8C93-454D-AD14-B164DC2F8E17Q30663040-7CFC6E5E-E160-4DA3-B7DA-D6A3A3284022Q30667762-82F3F1A9-4127-4E75-ABF6-F622E779187AQ33224008-F80675EF-E02E-4643-9798-A0F0501C0B9EQ33232299-3330D528-5068-4E13-8548-F232C47634B8Q33945043-4BF0F1D6-0524-491F-AE67-7B86B4C93E2FQ34315683-AF91D9F6-7AB9-4AD8-883D-BAC7292A749CQ34942068-B4DB046E-83E9-4709-8C78-3E7E29B6E541Q35027180-BF44B0ED-B83E-4C35-A96D-B18D4AF3C72BQ35801364-C6CBF5CA-2EEE-4F47-B1A4-6AF67FC3C983Q36522581-F9A50758-DEC8-4930-B4DB-D5C826C4C32CQ36917938-30765E71-D459-4E4F-A423-DD620F529EF3Q36940343-5B7FD150-511C-472F-8F66-31091C45435BQ36955856-F5ED7E6F-27F3-4280-8A1B-BBF065560AFDQ37024312-1BE0DC92-C1F0-4B13-ACEB-74E34BEE9575Q37737102-2237D474-ACBC-447D-9271-D46AE876D0B0Q37806094-900D1994-3023-4A4B-8D9A-5E914E9DE20AQ38115490-E1A54F84-CFA1-4746-83DE-3C0718EEAC1CQ38171392-A1915361-7F37-44E3-A1A8-846CF0EE5123Q38538479-81277DAA-DD45-4ED8-8111-91DA2DD9DFB8Q38676814-A53D4CDE-3D53-44E7-B4CD-03F1809A1463Q38777722-D4754B48-01C6-43BD-91B5-804E4269FF83Q39234425-15AFBADC-C6AC-450E-B408-4800493CD92EQ39318047-132E321A-8BA6-4D67-90DA-50B80ED521AFQ39346442-92085317-2498-4E1C-A611-F261E2E27C35Q41807967-D4748352-8F17-411B-AB1F-E075CF70B924Q41885592-C839B0C3-9F52-40EF-84EB-DB5DC7CE4C4CQ41978229-7D731442-3F05-47A9-A9C3-DA91BDD27C52Q42087361-80A20BC0-2B8F-423E-A485-2B52DC1903F2Q42105827-D9282CED-31C6-4959-A11E-E2194E43E2FEQ42374895-C4DB1A1D-019D-4184-B636-A2E18D52987E
P2860
description
2003 nî lūn-bûn
@nan
2003 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Rotational actuators based on carbon nanotubes.
@ast
Rotational actuators based on carbon nanotubes.
@en
Rotational actuators based on carbon nanotubes.
@nl
type
label
Rotational actuators based on carbon nanotubes.
@ast
Rotational actuators based on carbon nanotubes.
@en
Rotational actuators based on carbon nanotubes.
@nl
prefLabel
Rotational actuators based on carbon nanotubes.
@ast
Rotational actuators based on carbon nanotubes.
@en
Rotational actuators based on carbon nanotubes.
@nl
P2093
P2860
P356
P1433
P1476
Rotational actuators based on carbon nanotubes.
@en
P2093
A M Fennimore
M S Fuhrer
T D Yuzvinsky
Wei-Qiang Han
P2860
P2888
P304
P356
10.1038/NATURE01823
P407
P50
P577
2003-07-01T00:00:00Z
P5875
P6179
1052384493