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Photonics Dictionary

exciton

An exciton is a quasiparticle that represents the bound state of an electron and a hole in a solid-state material, typically a semiconductor or an insulator. In simpler terms, an exciton is a paired electron and hole created when an electron absorbs a photon and is promoted to a higher energy state, leaving behind an empty state called a hole.

Key characteristics of excitons include:

Formation: Excitons are formed when an electron in the valence band of a material is excited to the conduction band by absorbing a photon. This process leaves behind a hole (a positive charge) in the valence band.

Electron-hole pair: An exciton consists of a negatively charged electron and a positively charged hole, and these two particles are bound together by electrostatic forces. The electron and hole are attracted to each other, forming a stable excitonic state.

Binding energy: Excitons have a characteristic binding energy, which is the energy required to separate the electron and hole and break the exciton. The binding energy depends on the material and the specific conditions.

Mobility: Excitons can migrate through the material, and their mobility is influenced by factors such as temperature, the nature of the material, and the presence of defects. The movement of excitons plays a role in various optoelectronic processes.

Recombination: Excitons can recombine, wherein the electron and hole rejoin, releasing energy in the form of a photon. Recombination is a fundamental process in the emission of light from semiconductors, as seen in light-emitting diodes (LEDs) and lasers.

Types of excitons: Depending on the properties of the material and the excitonic state, different types of excitons can exist, such as Frenkel excitons (in molecular crystals) and Wannier-Mott excitons (in semiconductors).

Excitons play a crucial role in various optoelectronic devices, including solar cells, LEDs, and semiconductor lasers. Understanding the behavior and dynamics of excitons is essential for designing and optimizing these devices. Additionally, excitons are of interest in the field of condensed matter physics for studying the collective behavior of charge carriers in materials.

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