Your search keyword '"Gramotnev, Dmitri K."' showing total 11 results

1. Plasmon nanofocusing: New approaches in sensing and nanomanipulation

Author

Gramotnev, Dmitri K and Vogel, Michael W

Published

2009

2. Heating effects in nanofocusing metal wedges.

Author

Tan, Shiaw Juen and Gramotnev, Dmitri K.

Subjects

*PLASMONS (Physics), *HEATING, *BIOTECHNOLOGY, *PLASMA waveguides, *ENERGY dissipation

Abstract

This paper investigates theoretically and numerically local heating effects in plasmon nanofocusing structures with a particular focus on the sharp free-standing metal wedges. The developed model separates plasmon propagation in the wedge from the resultant heating effects. Therefore, this model is only applicable where the temperature increments in a nanofocusing structure are sufficiently small not to result in significant variations of the metal permittivity in the wedge. The problem is reduced to a one-dimensional heating model with a distributed heat source resulting from plasmon dissipation in the metal wedge. A simple heat conduction equation governing the local heating effects in a nanofocusing structure is derived and solved numerically for plasmonic pulses of different lengths and reasonable energies. Both the possibility of achieving substantial local temperature increments in the wedge (with a significant self-influence of the heating plasmonic pulses), and the possibility of relatively weak heating (to ensure the validity of the previously developed nanofocusing theory) are demonstrated and discussed, including the future applications of the obtained results. Applicability conditions for the developed model are also derived and discussed. [ABSTRACT FROM AUTHOR]

Published

2011

3. Optimized nonadiabatic nanofocusing of plasmons by tapered metal rods.

Author

Gramotnev, Dmitri K., Vogel, Michael W., and Stockman, Mark I.

Subjects

*PLASMONS (Physics), *BARS (Engineering), *METALS, *STRUCTURAL optimization, *ELECTRIC fields, *NANOSTRUCTURES, *MATHEMATICAL models

Abstract

Using rigorous numerical methods of analysis, this paper investigates nonadiabatic nanofocusing in tapered nanorods with the major emphasis on structural optimization for achieving maximal possible local field enhancement. Simple analytical equations for the determination of the optimal length of the tapered rod are presented and discussed. It is also shown that for the considered structures, optimal taper angle and optimal length of the rod only very weakly depend on the radius of curvature of the rounded tip of the rod. Contrary to this, enhancement of the local electric field at the rounded tip strongly increases with decreasing radius of the tip. Comparison of the numerical results with the adiabatic theory of nanofocusing results in accurate verification of the applicability conditions for adiabatic approximation in tapered nanorods. [ABSTRACT FROM AUTHOR]

Published

2008

4. Channel plasmon-polariton modes in V grooves filled with dielectric.

Author

Vernon, Kristy C., Gramotnev, Dmitri K., and Pile, D. F. P.

Subjects

*DIELECTRIC devices, *PERMITTIVITY, *PLASMONS (Physics), *POLARITONS, *NANOSTRUCTURES, *WAVEGUIDES

Abstract

We investigated the effect of dielectric filling in a V groove on the propagation parameters of channel plasmon-polariton (CPP) modes. In particular, existence conditions and critical groove angles, mode localization, field structure, dispersion, and propagation distances of CPP modes are analyzed as functions of dielectric permittivity inside the groove. It is demonstrated that increasing dielectric permittivity in the groove results in a rapid increase of mode localization near the tip of the groove and increase of both the critical angles that determine a range of groove angles for which CPP modes can exist. Detailed analysis of the field structure has demonstrated that the maximum of the field in a CPP mode is typically reached at a small distance from the tip of the groove. The effect of rounded tip is also investigated. [ABSTRACT FROM AUTHOR]

Published

2008

5. Adiabatic nanofocusing of plasmons by a sharp metal wedge on a dielectric substrate.

Author

Vernon, Kristy C., Gramotnev, Dmitri K., and Pile, David F. P.

Subjects

*NANOTECHNOLOGY, *PLASMONS (Physics), *DIELECTRICS, *THIN films, *MATERIALS science

Abstract

We demonstrate that efficient adiabatic nanofocusing of plasmons can be achieved using a sharp metal wedge (thin tapered film) on a dielectric substrate. It is shown that the quasisymmetric (with respect to the charge distribution across the wedge) plasmon mode can experience infinite adiabatic slowing down with both its phase and group velocities reducing to zero as the plasmon propagates towards the tip of the wedge. Conditions for strong local field enhancement near the tip are determined and analyzed. In particular, it is demonstrated that the electric field in the plasmon experiences much stronger local enhancement than the magnetic field. Two distinct asymptotic regimes with the electric field amplitude approaching either zero or infinity at the tip of the wedge (tapered film) are described. The results are compared to adiabatic nanofocusing of plasmons by metallic V grooves and sharp metal wedges in a uniform dielectric. [ABSTRACT FROM AUTHOR]

Published

2007

6. Nanofocusing of electromagnetic radiation.

Author

Gramotnev, Dmitri K. and Bozhevolnyi, Sergey I.

Subjects

*ELECTROMAGNETIC radiation, *DIELECTRICS, *PLASMONS (Physics), *NANOSTRUCTURES, *POLARITONS

Abstract

Nanofocusing of electromagnetic radiation, that is, reducing the cross sections of propagating optical modes far beyond the diffraction limit in dielectric media, can be achieved in tapered metal-dielectric waveguides that support surface plasmon-polariton modes. Although the main principles of nanofocusing were formulated over a decade ago, a deep theoretical understanding and conclusive experimental verification were achieved only a few years ago. These advances have spawned a variety of new important technological possibilities for the efficient delivery, control and manipulation of optical radiation on the nanoscale. Here, we present the underlying physical principles of radiation nanofocusing in metallic nanostructures, overview recent progress and major developments, and consider future directions and potential applications of this subfield of nano-optics. [ABSTRACT FROM AUTHOR]

Published

2014

7. Ultimate capabilities of sharp metal tips for plasmon nanofocusing, near-field trapping and sensing

Author

Gramotnev, Dmitri K. and Vogel, Michael W.

Subjects

*PLASMONS (Physics), *NEAR-fields, *SURFACE plasmon resonance, *LOCAL fields (Algebra), *NANOPARTICLES, *OPTICAL detectors, *IMAGING systems

Abstract

Abstract: This Letter considers an ‘ultimate’ nanofocusing system with arguably the largest field enhancements achievable in plasmonic nanofocusing structures. These enhancements appear far beyond those required for single molecule detection. The proposed structure is demonstrated to be ∼4 orders of magnitude more efficient for trapping of small nanoparticles and single molecules, than the tip-assisted trapping. It does not require direct irradiation of the tip, and this will enable highly targeted delivery of the optical energy to nanoscale regions as small as a few nanometers (e.g., inside living cells) for trapping, imaging, localized heat discharge, and superior sensing in a new generation of nano-optical detectors. [Copyright &y& Elsevier]

Published

2011

8. Plasmonics beyond the diffraction limit.

Author

Gramotnev, Dmitri K. and Bozhevolnyi, Sergey I.

Subjects

*NANOPHOTONICS, *OPTICAL diffraction, *PLASMONS (Physics), *POLARITONS, *ELECTROMAGNETIC waves

Abstract

Recent years have seen a rapid expansion of research into nanophotonics based on surface plasmon–polaritons. These electromagnetic waves propagate along metal–dielectric interfaces and can be guided by metallic nanostructures beyond the diffraction limit. This remarkable capability has unique prospects for the design of highly integrated photonic signal-processing systems, nanoresolution optical imaging techniques and sensors. This Review summarizes the basic principles and major achievements of plasmon guiding, and details the current state-of-the-art in subwavelength plasmonic waveguides, passive and active nanoplasmonic components for the generation, manipulation and detection of radiation, and configurations for the nanofocusing of light. Potential future developments and applications of nanophotonic devices and circuits are also discussed, such as in optical signals processing, nanoscale optical devices and near-field microscopy with nanoscale resolution. [ABSTRACT FROM AUTHOR]

Published

2010

9. Adiabatic nano-focusing of plasmons by metallic tapered rods in the presence of dissipation

Author

Vogel, Michael W. and Gramotnev, Dmitri K.

Subjects

*PLASMONS (Physics), *ENERGY dissipation, *QUASIPARTICLES, *LOW temperatures

Abstract

Abstract: We investigate the effect of dissipation on adiabatic nano-focusing of surface plasmons in a sharp metal tapered rod. Three distinct patterns of nano-focusing and local field enhancement are predicted at different levels of dissipation and/or taper angles. Critical structural parameters and asymptotic behavior of the field near the tip are analyzed. [Copyright &y& Elsevier]

Published

2007

10. New Plasmon Waveguides Composed of Twin Metal Wedges with a Nano Gap.

Author

Haraguchi, Masanobu, Pile, David F. P., Okamoto, Toshihiro, Fukui, Masuo, and Gramotnev, Dmitri K.

Subjects

PLASMONS (Physics), DISPERSION relations, NUCLEAR physics, QUANTUM theory, OPTICAL waveguides, EXCITON theory

Abstract

The article discusses the existence of coupled wedge plasmons (CWP) which propagates along a nano gap of twin metal wedges. This CWP were formed by wedge plasmons which can interact with each other. The study has stated that the dispersion relations of the wavenumber, propagation distance, and beam area of CWP, have showed that the characteristics of CWP were similar to wedge plasmons and gap plasmons.

Published

2006

11. Shape effects in tapered metal rods during adiabatic nanofocusing of plasmons.

Author

Vogel, Michael W. and Gramotnev, Dmitri K.

Subjects

*PLASMONS (Physics), *QUANTUM perturbations, *PHOTONICS, *NEAR-field microscopy, *NANOSTRUCTURED materials, *ISOELECTRIC focusing, *METALS

Abstract

We studied adiabatic nanofocusing of strongly localized surface plasmons in tapered metal rods with parabolic perturbations of the conical shape of the taper. Typical plasmon propagation parameters and local field enhancements are determined along the tapered rod, depending on the shape and plasmon frequency (wavelength). In particular, it is demonstrated that metal rods with tapered convex shape are more efficient in achieving larger local field enhancements at the tip, as compared to rods with the concave shape of the taper. This is explained by weaker dissipative losses in tapered rods with convex shape. In addition, plasmon nanofocusing in tapered rods with convex shape is less sensitive to further variations of the shape. As a result, it is demonstrated that tapered rods with the convex shape could be advantageous for practical applications where strong local field enhancement near the tip is required, and/or where metal rods with relatively large dissipation are used. The obtained results will be important for optimization and practical fabrication of efficient nanofocusing structures using tapered metal rods. [ABSTRACT FROM AUTHOR]

Published

2010