Literature DB >> 28447977

Plasmonic Trapping and Release of Nanoparticles in a Monitoring Environment.

Jung-Dae Kim1, Yong-Gu Lee2.   

Abstract

Plasmonic tweezers use surface plasmon polaritons to confine polarizable nanoscale objects. Among the various designs of plasmonic tweezers, only a few can observe immobilized particles. Moreover, a limited number of studies have experimentally measured the exertable forces on the particles. The designs can be classified as the protruding nanodisk type or the suppressed nanohole type. For the latter, microscopic observation is extremely challenging. In this paper, a new plasmonic tweezer system is introduced to monitor particles, both in directions parallel and orthogonal to the symmetric axis of a plasmonic nanohole structure. This feature enables us to observe the movement of each particle near the rim of the nanohole. Furthermore, we can quantitatively estimate the maximal trapping forces using a new fluidic channel.

Mesh:

Year:  2017        PMID: 28447977      PMCID: PMC5564470          DOI: 10.3791/55258

Source DB:  PubMed          Journal:  J Vis Exp        ISSN: 1940-087X            Impact factor:   1.355


  16 in total

1.  Optical trapping of a single protein.

Authors:  Yuanjie Pang; Reuven Gordon
Journal:  Nano Lett       Date:  2011-12-16       Impact factor: 11.189

2.  Low-power nano-optical vortex trapping via plasmonic diabolo nanoantennas.

Authors:  Ju-Hyung Kang; Kipom Kim; Ho-Seok Ee; Yong-Hee Lee; Tae-Young Yoon; Min-Kyo Seo; Hong-Gyu Park
Journal:  Nat Commun       Date:  2011-12-13       Impact factor: 14.919

3.  Plasmonic Optical Tweezers toward Molecular Manipulation: Tailoring Plasmonic Nanostructure, Light Source, and Resonant Trapping.

Authors:  Tatsuya Shoji; Yasuyuki Tsuboi
Journal:  J Phys Chem Lett       Date:  2014-08-23       Impact factor: 6.475

4.  Nano-optical trapping of Rayleigh particles and Escherichia coli bacteria with resonant optical antennas.

Authors:  M Righini; P Ghenuche; S Cherukulappurath; V Myroshnychenko; F J García de Abajo; R Quidant
Journal:  Nano Lett       Date:  2009-10       Impact factor: 11.189

5.  Transport and trapping in two-dimensional nanoscale plasmonic optical lattice.

Authors:  Kuan-Yu Chen; An-Ting Lee; Chia-Chun Hung; Jer-Shing Huang; Ya-Tang Yang
Journal:  Nano Lett       Date:  2013-08-20       Impact factor: 11.189

6.  Optical trapping of 12 nm dielectric spheres using double-nanoholes in a gold film.

Authors:  Yuanjie Pang; Reuven Gordon
Journal:  Nano Lett       Date:  2011-08-15       Impact factor: 11.189

7.  Permanent fixing or reversible trapping and release of DNA micropatterns on a gold nanostructure using continuous-wave or femtosecond-pulsed near-infrared laser light.

Authors:  Tatsuya Shoji; Junki Saitoh; Noboru Kitamura; Fumika Nagasawa; Kei Murakoshi; Hiroaki Yamauchi; Syoji Ito; Hiroshi Miyasaka; Hajime Ishihara; Yasuyuki Tsuboi
Journal:  J Am Chem Soc       Date:  2013-04-23       Impact factor: 15.419

8.  Three-dimensional manipulation with scanning near-field optical nanotweezers.

Authors:  J Berthelot; S S Aćimović; M L Juan; M P Kreuzer; J Renger; R Quidant
Journal:  Nat Nanotechnol       Date:  2014-03-02       Impact factor: 39.213

9.  A microfluidic device based on gravity and electric force driving for flow cytometry and fluorescence activated cell sorting.

Authors:  Bo Yao; Guo-an Luo; Xue Feng; Wei Wang; Ling-xin Chen; Yi-ming Wang
Journal:  Lab Chip       Date:  2004-11-10       Impact factor: 6.799

10.  Trapping of a single DNA molecule using nanoplasmonic structures for biosensor applications.

Authors:  Jung-Dae Kim; Yong-Gu Lee
Journal:  Biomed Opt Express       Date:  2014-07-03       Impact factor: 3.732
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