about
Rotational manipulation of single cells and organisms using acoustic waves.Man-made rotary nanomotors: a review of recent developments.Selectively manipulable acoustic-powered microswimmers.Nonequilibrium molecular transport photoinduced by potential energy fluctuations.Symmetry interplay in Brownian photomotors: From a single-molecule device to ensemble transport.Controlled clockwise and anticlockwise rotational switching of a molecular motor.Negative optical torque.Fabrication and robotization of ultrasensitive plasmonic nanosensors for molecule detection with Raman scattering.Bridging the Two Worlds: A Universal Interface between Enzymatic and DNA Computing Systems.Laser propulsion of nanobullets by adiabatic compression of surface plasmon polaritons.Photon-induced generation and spatial control of extreme pressure at the nanoscale with a gold bowtie nano-antenna platform.Lateral forces on circularly polarizable particles near a surface.Ultra-durable rotary micromotors assembled from nanoentities by electric fields.Optical Twist Induced by Plasmonic Resonance.Origin and Future of Plasmonic Optical Tweezers.Lateral optical force on chiral particles near a surface.Surfactant-assisted, shape-controlled synthesis of gold nanocrystals.A Force to Be Reckoned With: A Review of Synthetic Microswimmers Powered by Ultrasound.Recent Progress on Man-Made Inorganic Nanomachines.Wavelength-selective orbital angular momentum generation based on a plasmonic metasurface.A vesicle cell under collision with a Janus or homogeneous nanoparticle: translocation dynamics and late-stage morphology.Micro/nanomotors towards in vivo application: cell, tissue and biofluid.Template electrosynthesis of tailored-made helical nanoswimmers.Electromagnetic stress at the boundary: Photon pressure or tension?Joining plasmonics with microfluidics: from convenience to inevitability.Topologically enabled optical nanomotors.Acoustofluidic Rotational Manipulation of Cells and Organisms Using Oscillating Solid Structures.Neutrophil-inspired propulsion in a combined acoustic and magnetic field.Orthogonal navigation of multiple visible-light-driven artificial microswimmers.Imaging the transient heat generation of individual nanostructures with a mechanoresponsive polymer.Light-driven micro/nanomotors: from fundamentals to applications.Trapping and rotating nanoparticles using a plasmonic nano-tweezer with an integrated heat sink.Giant and tunable optical torque for micro-motors by increased force arm and resonantly enhanced force.Optical Force Enhancement Using an Imaginary Vector Potential for Photons.Transport of alignment active particles in funnel structures.Rotating-Electric-Field-Induced Carbon-Nanotube-Based Nanomotor in Water: A Molecular Dynamics Study.Light-Induced Pulling and Pushing by the Synergic Effect of Optical Force and Photophoretic Force.Sculpting nanoparticle dynamics for single-bacteria-level screening and direct binding-efficiency measurement.Director/barycentric rotation in cholesteric droplets under temperature gradient.Controlling the plasmonic orbital angular momentum by combining the geometric and dynamic phases.
P2860
Q27322778-6D35A473-AA90-45CD-8CA2-A7AE35E30ABDQ30356007-7B0FEC85-0A07-421D-950B-61815D8F1A9AQ30410562-D8316228-AB51-4046-9602-265185D0082AQ33807455-100DD337-A13C-48C5-8934-CF30C8F2BFDBQ34423833-6304CDF4-8FF5-4EC7-B876-34930D265CF1Q34522055-F6ACA011-DB42-42BF-A104-DFC3A2B40FB6Q35256284-2B629DB2-B050-48BB-B1B0-C41F23927219Q35785675-E4B5DCD9-BC4D-4B66-A7B5-9E43F1341A7AQ35831566-0AF64449-56E6-4FF7-9BA4-8A9EF13CECDCQ35859619-F85A2D6A-D7D8-421D-8DA5-5F6328FF3DC1Q36156030-307239D0-B86F-4D5F-B42E-AE74AEA9EE0BQ36357007-6F818148-B5F6-4057-A9FB-8CF823D728B6Q36955856-CABE94D8-21C3-47ED-8B10-6680283FAF0FQ36996303-20C378D9-A7A2-49BA-8E16-9E9C3CE25063Q37646398-B55173C0-727F-4AE0-9B19-28E344AB22FEQ37646668-F6FECE4E-1305-4418-A3B0-9C54347A5E80Q37835024-5A9B058D-441A-4D01-B0D7-134ED2A759CAQ38410405-A2BFE86B-793D-42B5-84EF-AEE43DAA274EQ38538479-A348F89E-56C2-483B-9946-C12EF6725772Q38856921-A7EF4BE2-E175-4B34-A436-D3EB6E7F8A60Q39303247-269B24CE-A80F-491A-8B59-90BA3402FBFDQ39318047-69F74BD5-C881-4CE1-9DC1-5572AC0043EEQ39332609-4A4E5412-87DB-43AC-91C0-0D17A2586742Q39353046-BCABB1A9-9029-4FA6-B59F-A452457EAD9BQ39575053-17E9A9AD-152A-4D4C-850C-B312EF8F0A92Q40986944-0B1565AB-EDC9-4959-BEB0-8E31C237B464Q41657525-E374FBC2-18D8-45AF-ABAE-D2E3334F896EQ42054744-3B99C922-B98D-4CF3-94AE-74D9A47DE216Q44909961-E9B08F80-6F81-4768-9B97-458CEA4A7465Q46093030-8A0F77F2-B379-4BDF-82E0-02F433CA9798Q47928952-73CCA92D-038D-4E37-A5DB-09B31C793314Q48111367-4642FF1B-1A25-431D-8445-B50790BCC6E2Q49925625-D00BA36F-E3EF-4833-8366-039FC9B6D87FQ50004834-6FC03DE8-5277-4D2E-B888-818A4B60034BQ50868736-B70385D9-5BB2-4774-BF12-5955C9D0FEA9Q50933692-C7A62502-5F51-494F-A334-3334EE0CEF6FQ51009443-C6FCF358-E76C-4FB5-9A5E-A047976A48EEQ52684346-286C37D0-1BC3-43EF-BF40-F6EE45DF36A3Q53540581-EABD130C-A1B0-44AB-A725-0344FCDA680AQ54365805-91CB40FD-0577-42EE-8B9A-A1391EB52750
P2860
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh-hant
name
Light-driven nanoscale plasmonic motors.
@en
Light-driven nanoscale plasmonic motors.
@nl
type
label
Light-driven nanoscale plasmonic motors.
@en
Light-driven nanoscale plasmonic motors.
@nl
prefLabel
Light-driven nanoscale plasmonic motors.
@en
Light-driven nanoscale plasmonic motors.
@nl
P2093
P356
P1476
Light-driven nanoscale plasmonic motors.
@en
P2093
Guy Bartal
Thomas Zentgraf
Xiang Zhang
Yongmin Liu
P2888
P304
P356
10.1038/NNANO.2010.128
P577
2010-07-04T00:00:00Z
P5875
P6179
1021869091