Temperature-Dependent Evolution of Coherence, Entropy, and Photon Statistics in Photoluminescence

TL;DR

This paper introduces a fundamental relationship linking chemical potential to temperature and material properties in photoluminescence, enabling analysis of temperature-dependent optical properties and transition behaviors.

Contribution

It establishes a novel framework that models photoluminescence akin to thermal radiation, capturing temperature effects on spectral, coherence, and statistical properties for the first time.

Findings

Identification of a temperature range with quasi-conserved emission rate

Observation of a rapid transition to thermal behavior in chemical potential and entropy

Smooth evolution of coherence time and photon statistics across temperatures

Abstract

Photoluminescence (PL) is a fundamental light-matter interaction in which absorbed photons are re-emitted, playing a key role in science and engineering. It is commonly modeled by introducing a non-zero chemical potential into Planck's law to capture its deviation from thermal emission. In this work, we establish, for the first time to our knowledge, a fundamental relationship that expresses the chemical potential as a function of temperature, material properties, and excitation conditions, enabling a treatment of PL analogous to Planck's law with thermal radiation. This formulation allows for the analysis of temperature-dependent PL properties, including spectral emission, entropy, temporal coherence, and photon statistics, capturing the transition from narrowband pump-induced to broadband thermal emission. Notably, we identify a temperature range where the emission rate is quasi-conserved, associated with the previously reported blueshift. This is followed by a rapid transition to thermal behavior, reflected in both the chemical potential and entropy. Conversely, the coherence time and photon statistics evolve smoothly across the entire temperature range. Alongside its scientific contribution, this framework provides a foundation for designing temperature-tunable light sources, enabling control over coherence length and photon statistics.