Article | REF: NM2035 V1

Carbon Nanotube Photoluminescence

Authors: Nicolas IZARD, Jean-Sébastien LAURET, Éric ANGLARET

Publication date: January 10, 2016

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ABSTRACT

Single-wall carbon nanotubes (SWNTs) display unusual physical properties owing to their smallness and their all-carbon composition. Concerning their optical properties, semiconductor SWNT emit light in the near infrared – a phenomenon called fluorescence or photoluminescence – at wavelengths that depend on their structure and dielectric environment. This article concerns the physical phenomena responsible for SWNT photoluminescence, and in particular the excitonic properties of these entities, the influence of their structure and environment on their photoluminescence spectrum, and on their possible applications in photonics.

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AUTHORS

  • Nicolas IZARD: CNRS research fellow - Charles Coulomb Laboratory, University of Montpellier, France

  • Jean-Sébastien LAURET: University Professor - Aimé Cotton Laboratory, University of Paris-Sud, Orsay, France

  • Éric ANGLARET: University Professor - Charles Coulomb Laboratory, University of Montpellier, France

 INTRODUCTION

Carbon is an amazing element, capable of forming many types of chemical bonds with other carbon atoms, leading to a wide variety of existing carbon forms. Single-walled carbon nanotubes (SWNTs) are a particularly interesting form of carbon, thanks to their low dimensionality and model structure, which give them original physical properties. Depending on their structure, SWNTs can be metallic or semiconducting. With regard to their optical properties, semiconducting SWNTs emit light in the near infrared, a phenomenon known as photoluminescence. The emission wavelengths of SWNTs are highly dependent on their structure, as well as their dielectric environment.

In this article, we discuss the physical phenomena behind the photoluminescence of semiconductor nanotubes. In particular, we describe the excitonic nature of the photoluminescence mechanism, and the strong influence of environment and structure on photoluminescence spectra. The photoluminescence properties of nanotubes are very rich, and can be put to use in a wide range of applications such as metrology, materials characterization and biological imaging. We will examine in detail the photoluminescence applications of carbon nanotubes in the field of photonics, whether for quantum information, or the realization of active optical components such as light sources or detectors.

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KEYWORDS

carbon nanotubes   |   photoluminescence


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Photoluminescence of carbon nanotubes