Plasmon Particle Array Lasers

Y. Hadad; A. H. Schokker; F. van Riggelen; A. Alù; A. F. Koenderink

doi:10.1007/978-3-319-45820-5_8

Plasmon Particle Array Lasers

Y. Hadad, A. H. Schokker, F. van Riggelen, A. Alù, A. F. Koenderink

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

1 Scopus citations

Abstract

Diffractive arrays of strongly scattering noble metal particles coupled to a high-index slab of gain material can form the basis for plasmonic distributed feedback lasers. In this chapter, we discuss recent theoretical and experimental results describing the electromagnetic properties of these structures. Particularly, we investigate bandgap topology versus detuning between the plasmonic and Bragg resonances. We examine the complex dispersion relation, accounting for the fact that the particles are electrodynamic scatterers with radiation loss, that couple via a stratified medium system supporting guided modes. From the complex dispersion of this array we can deduce loss and outcoupling properties of the various Bloch modes, giving a handle on its lasing properties. From the experimental side, we show how to measure the dispersion relation using fluorescence microscopy, and systematically examine the array dispersion for realized plasmonic lasers as function of detuning between particle and lattice resonance. We conclude the chapter with a vision towards employing disordered, quasiperiodic and random plasmonic arrays to induce different optical responses, and experimentally demonstrate the exceptional robustness of lasing to disorder in these systems.

Original language	English
Title of host publication	Springer Series in Solid-State Sciences
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	165-190
Number of pages	26
DOIs	https://doi.org/10.1007/978-3-319-45820-5_8
State	Published - 1 Jan 2017
Externally published	Yes

Publication series

Name	Springer Series in Solid-State Sciences
Volume	185
ISSN (Print)	0171-1873
ISSN (Electronic)	2197-4179

Keywords

Bragg Resonance
Gain Medium
Internal Quantum Efficiency
Surface Enhance Raman Scattering
Waveguide Mode

ASJC Scopus subject areas

Condensed Matter Physics

Access to Document

10.1007/978-3-319-45820-5_8

Cite this

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title = "Plasmon Particle Array Lasers",

abstract = "Diffractive arrays of strongly scattering noble metal particles coupled to a high-index slab of gain material can form the basis for plasmonic distributed feedback lasers. In this chapter, we discuss recent theoretical and experimental results describing the electromagnetic properties of these structures. Particularly, we investigate bandgap topology versus detuning between the plasmonic and Bragg resonances. We examine the complex dispersion relation, accounting for the fact that the particles are electrodynamic scatterers with radiation loss, that couple via a stratified medium system supporting guided modes. From the complex dispersion of this array we can deduce loss and outcoupling properties of the various Bloch modes, giving a handle on its lasing properties. From the experimental side, we show how to measure the dispersion relation using fluorescence microscopy, and systematically examine the array dispersion for realized plasmonic lasers as function of detuning between particle and lattice resonance. We conclude the chapter with a vision towards employing disordered, quasiperiodic and random plasmonic arrays to induce different optical responses, and experimentally demonstrate the exceptional robustness of lasing to disorder in these systems.",

keywords = "Bragg Resonance, Gain Medium, Internal Quantum Efficiency, Surface Enhance Raman Scattering, Waveguide Mode",

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T1 - Plasmon Particle Array Lasers

AU - Hadad, Y.

AU - Schokker, A. H.

AU - van Riggelen, F.

AU - Alù, A.

AU - Koenderink, A. F.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - Diffractive arrays of strongly scattering noble metal particles coupled to a high-index slab of gain material can form the basis for plasmonic distributed feedback lasers. In this chapter, we discuss recent theoretical and experimental results describing the electromagnetic properties of these structures. Particularly, we investigate bandgap topology versus detuning between the plasmonic and Bragg resonances. We examine the complex dispersion relation, accounting for the fact that the particles are electrodynamic scatterers with radiation loss, that couple via a stratified medium system supporting guided modes. From the complex dispersion of this array we can deduce loss and outcoupling properties of the various Bloch modes, giving a handle on its lasing properties. From the experimental side, we show how to measure the dispersion relation using fluorescence microscopy, and systematically examine the array dispersion for realized plasmonic lasers as function of detuning between particle and lattice resonance. We conclude the chapter with a vision towards employing disordered, quasiperiodic and random plasmonic arrays to induce different optical responses, and experimentally demonstrate the exceptional robustness of lasing to disorder in these systems.

AB - Diffractive arrays of strongly scattering noble metal particles coupled to a high-index slab of gain material can form the basis for plasmonic distributed feedback lasers. In this chapter, we discuss recent theoretical and experimental results describing the electromagnetic properties of these structures. Particularly, we investigate bandgap topology versus detuning between the plasmonic and Bragg resonances. We examine the complex dispersion relation, accounting for the fact that the particles are electrodynamic scatterers with radiation loss, that couple via a stratified medium system supporting guided modes. From the complex dispersion of this array we can deduce loss and outcoupling properties of the various Bloch modes, giving a handle on its lasing properties. From the experimental side, we show how to measure the dispersion relation using fluorescence microscopy, and systematically examine the array dispersion for realized plasmonic lasers as function of detuning between particle and lattice resonance. We conclude the chapter with a vision towards employing disordered, quasiperiodic and random plasmonic arrays to induce different optical responses, and experimentally demonstrate the exceptional robustness of lasing to disorder in these systems.

KW - Bragg Resonance

KW - Gain Medium

KW - Internal Quantum Efficiency

KW - Surface Enhance Raman Scattering

KW - Waveguide Mode

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BT - Springer Series in Solid-State Sciences

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ER -

Plasmon Particle Array Lasers

Abstract

Publication series

Keywords

ASJC Scopus subject areas

Access to Document

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