Ari Requicha scite author profile

Achieving control of light-material interactions for photonic device applications at nanoscale dimensions will require structures that guide electromagnetic energy with a lateral mode confinement below the diffraction limit of light. This cannot be achieved by using conventional waveguides or photonic crystals. It has been suggested that electromagnetic energy can be guided below the diffraction limit along chains of closely spaced metal nanoparticles that convert the optical mode into non-radiating surface plasmons. A variety of methods such as electron beam lithography and self-assembly have been used to construct metal nanoparticle plasmon waveguides. However, all investigations of the optical properties of these waveguides have so far been confined to collective excitations, and direct experimental evidence for energy transport along plasmon waveguides has proved elusive. Here we present observations of electromagnetic energy transport from a localized subwavelength source to a localized detector over distances of about 0.5 microm in plasmon waveguides consisting of closely spaced silver rods. The waveguides are excited by the tip of a near-field scanning optical microscope, and energy transport is probed by using fluorescent nanospheres.

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Plasmonics-A Route to Nanoscale Optical Devices

Maier

et al. 2001

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Representations for Rigid Solids: Theory, Methods, and Systems

1980

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Nanorobots, NEMS, and Nanoassembly

2003

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Compensation of Scanner Creep and Hysteresis for AFM Nanomanipulation

Mokaberi

Requicha

2008

IEEE Trans. Automat. Sci. Eng.

178

102

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Nanomanipulation with atomic force microscopes (AFMs) for nanoparticles with overall sizes on the order of 10 nm has been hampered in the past by the large spatial uncertainties encountered in tip positioning. This paper addresses the compensation of nonlinear effects of creep and hysteresis on the piezo scanners which drive most AFMs. Creep and hysteresis are modeled as the superposition of fundamental operators, and their inverse model is obtained by using the inversion properties of the Prandtl-Ishlinskii operator. Identification of the parameters in the forward model is achieved by a novel method that uses the topography of the sample and does not require position sensors. The identified parameters are used to compute the inverse model, which in turn serves to drive the AFM in an open-loop, feedforward scheme. Experimental results show that this approach effectively reduces the spatial uncertainties associated with creep and hysteresis, and supports automated, computer-controlled manipulation operations that otherwise would fail.Note to Practitioners-Manipulation at the nanoscale by using AFMs as sensory robots is well established in research laboratories, and has great potential as a process for prototyping nanodevices and systems, for repairing structures built by other means, and for small batch manufacturing by using multitip arrays. However, precise (to 1 nm, say) AFM nanomanipulation is currently very labor intensive, primarily because of the uncertainty in the position of the AFM tip relative to the sample being manipulated. Positional errors are due to thermal drift and various nonlinearities exhibited by the piezoelectric scanners used by most AFMs. This paper describes a technique for compensating creep and hysteresis, which, after drift, are the major causes of spatial uncertainty in AFMs. The compensator introduced here has been tested experimentally and shown to reduce creep and hysteresis effects by more than an order of magnitude. The creep and hysteresis compensator in this paper, together with the drift compensation scheme discussed in an earlier paper by the authors, provide means to reduce spatial uncertainties to a level that enables automatic manipulation, without a user in the loop, and therefore promise to greatly increase the throughput and accuracy of nanomanipulation operations.

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Ari Requicha

Local detection of electromagnetic energy transport below the diffraction limit in metal nanoparticle plasmon waveguides

Plasmonics-A Route to Nanoscale Optical Devices

Representations for Rigid Solids: Theory, Methods, and Systems

Nanorobots, NEMS, and Nanoassembly

Compensation of Scanner Creep and Hysteresis for AFM Nanomanipulation

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