Spontaneous emission and Purcell effect: some aspects

TL;DR

This chapter provides a comprehensive overview of spontaneous emission and the Purcell effect, highlighting theoretical foundations, experimental strategies for control, and implications for quantum and nano-optics technologies.

Contribution

It offers an integrated review of classical and quantum electromagnetic theories and discusses modern methods for tailoring spontaneous emission using engineered environments.

Findings

Enhanced understanding of SE modulation mechanisms

Analysis of advanced materials for controlling emission

Implications for quantum technology applications

Abstract

This chapter, part of the Proceedings of the III International Workshop on Quantum Nonstationary Systems (eds. Alexandre Dodonov and Lucas Chibebe Celeri), held in Brasilia in August 2024, offers a comprehensive overview of spontaneous emission (SE) and the Purcell effect within the broader context of quantum electrodynamics (QED) and vacuum fluctuations. It begins with a historical and theoretical review, tracing the development of classical and quantum electromagnetic theories. The chapter then examines how the SE rate of a quantum emitter is fundamentally influenced by its electromagnetic environment, the so-called Purcell effect, through canonical examples, such as emitters near perfectly conducting plates and inside cavities, as well as more advanced scenarios. Special attention is given to modern strategies for tailoring SE using engineered environments, including plasmonic cloaks, composite media near percolation thresholds, metal-insulator phase transitions, and strain-induced modulation in phosphorene. Analytical techniques, such as mode summation and Green's function formalism, are employed to describe how surrounding materials and boundary conditions affect local field modes and the local density of states. The findings underscore both the theoretical depth and experimental relevance of SE modulation, paving the way for innovations in nano-optics, quantum technologies, and advanced material design.