Simultaneous Magnetic Manipulation and Fluorescent Tracking of Multiple Individual Hybrid Nanostructures

Ruan, Gang; Vieira, G.; Henighan, Thomas; Chen, Aaron; Thakur, Dhananjay; Sooryakumar, R.; Winter, Jessica O.

doi:10.1021/nl1011855

Cited by 98 publications

(123 citation statements)

References 29 publications

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“…Once the bead is trapped in the potential well of the DW, the DW can be used to manipulate individual beads. Indeed, bead transport has been realized by either stepping a bead from one DW trap site to the next 19,[21][22][23][24]27 or moving it continuously with a propagating DW 20,22,25,26 . Continuous transport is limited, however, by the maximum interaction force, or binding force , between the bead and DW, which must overcome the hydrodynamic drag force on the bead as it is pulled through the host fluid 20 .…”

Section: Magnetic Bead-dw Interactionmentioning

confidence: 99%

Transport dynamics of superparamagnetic microbeads trapped by mobile magnetic domain walls

Rapoport

Beach

2013

Phys. Rev. B

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The dynamics of fluid-borne superparamagnetic bead transport by field-driven domain walls in submicrometer ferromagnetic tracks is studied experimentally together with numerical and analytical modeling. A combination of micromagnetic modeling and numerical calculation is used to determine the strength of bead-domain wall interaction for a range of track geometries and bead sizes. The maximum domain wall velocity for continuous bead transport is predicted from these results and shown to be supported by experimental measurements. Enhancement of the maximum velocity by appropriate material selection or field application is demonstrated and an analysis of the source of statistical variation is presented. Finally, the dynamics of beaddomain wall interaction and bead transport above the maximum domain wall velocity for continuous domain wall-mediated bead transport is characterized.Submitted to Phys. Rev. B 2

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Section: Magnetic Bead-dw Interactionmentioning

confidence: 99%

Transport dynamics of superparamagnetic microbeads trapped by mobile magnetic domain walls

Rapoport

Beach

2013

Phys. Rev. B

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“…Localised magnetic charges can be supported at the interconnections and the ability to manipulate magnetic charges in the form of magnetic domain walls (DWs) provides the basis for novel technological devices including information processing 1 and through the manipulation of bio-or chemically-functionalised magnetic nanoparticles. [2][3][4][5][6] Additionally, the patterning of 'artificial spin ice' geometries can give rise to a large number of energetically equivalent states which has been explored in both dipolar coupled systems 7,8 and interconnected networks. 9 Such structures have been suggested for macroscopic studies of fundamental frustrated phenomena and their associated emergent behavior showing strong links to the thermodynamics of the system.…”

Section: Introductionmentioning

confidence: 99%

Angular-dependent magnetization reversal processes in artificial spin ice

2015

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The angular dependence to the magnetization reversal in interconnected kagome artificial spin ice structures has been studied through experimental MOKE measurements and micromagnetic simulations. This reversal is mediated by the propagation of magnetic domain walls along the interconnecting bars which either nucleate at the vertex or arrive following an interaction in a neighbouring vertex. The physical differences in these processes show a distinct angular dependence allowing the different contributions to be identified. The configuration of the initial magnetization state, either locally or on a full sublattice of the system, controls the reversal characteristics of the array within a certain field window. This shows how the available magnetization reversal routes can be manipulated and the system trained.

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“…This opens up a channel for energy dissipation via spin wave emission, allowing a domain wall to maintain its spin structure during propagation. Magnetic domain wall (DW) motion is significant in wide ranging applications, from spintronic technologies for data storage, 1 processing, 2 and sensing applications 3 to the manipulation of atoms 4 and nanoparticles 5 for nanoassembly or nanodelivery. Typically, DW velocity increases linearly with field 3,6 up to the Walker field, where periodic transformations of the DW spin structure results in a dramatic reduction in time-averaged DW velocity, known as Walker breakdown.…”

mentioning

confidence: 99%

Suppression of Walker breakdown in magnetic domain wall propagation through structural control of spin wave emission

Burn

Atkinson

2013

Applied Physics Letters

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Simultaneous Magnetic Manipulation and Fluorescent Tracking of Multiple Individual Hybrid Nanostructures

Cited by 98 publications

References 29 publications

Transport dynamics of superparamagnetic microbeads trapped by mobile magnetic domain walls

Transport dynamics of superparamagnetic microbeads trapped by mobile magnetic domain walls

Angular-dependent magnetization reversal processes in artificial spin ice

Suppression of Walker breakdown in magnetic domain wall propagation through structural control of spin wave emission

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