Andreas Wacker
Professor
Nonresonant two-level transitions: Insights from quantum thermodynamics
Author
Summary, in English
Based on concepts from quantum thermodynamics, the two-level system coupled to a single electromagnetic
mode is analyzed. Focusing on the case of detuning, where the mode frequency does not match the transition
frequency, effective energies are derived for the levels and the photon energy. It is shown that these should be used
for energy exchange with fermionic and bosonic reservoirs in the steady state to achieve a thermodynamically
consistent description. While recovering known features such as frequency pulling or Bloch gain, this sheds light
on their thermodynamic background and allows for a coherent understanding.
mode is analyzed. Focusing on the case of detuning, where the mode frequency does not match the transition
frequency, effective energies are derived for the levels and the photon energy. It is shown that these should be used
for energy exchange with fermionic and bosonic reservoirs in the steady state to achieve a thermodynamically
consistent description. While recovering known features such as frequency pulling or Bloch gain, this sheds light
on their thermodynamic background and allows for a coherent understanding.
Department/s
- Mathematical Physics
- NanoLund: Center for Nanoscience
Publishing year
2022
Language
English
Publication/Series
Physical Review A
Volume
105
Document type
Journal article
Publisher
American Physical Society
Topic
- Atom and Molecular Physics and Optics
Status
Published
Project
- Quantum Cascade Lasers beyond general paradigms
- KAW Project: Nanothermodynamics for optoelectronic semiconductor devices
ISBN/ISSN/Other
- ISSN: 2469-9926