Breakdown of Detailed Balance for Thermal Radiation by Synthetic Fields

In recent times the possibility of nonreciprocity in heat transfer between two bodies has been extensively studied. In particular the role of strong magnetic fields has been investigated. A much simpler approach with considerable flexibility would be to consider heat transfer in synthetic electric and magnetic fields that are easily applied. We demonstrate the breakdown of detailed balance for the heat transfer function T(w), i.e., the spectrum of heat transfer between two objects due to the presence of synthetic electric and magnetic fields. The spectral measurements carry much more physical information and are the reason for the quantum theory of radiation. We demonstrate explicitly the synthetic field induced nonreciprocity in the heat transfer transmission function between two graphene flakes and for the Casimir coupling between two objects. Unlike many other cases of heat transfer, the latter case has interesting features of the strong coupling. Further the presence of synthetic fields affects the mean occupation numbers of two membranes and we propose this system for the experimental verification of the breakdown of detailed balance.

Automated summary

The possibility of nonreciprocity in heat transfer between two bodies has been extensively studied, especially the role of strong magnetic fields. A simpler approach would be to consider heat transfer in synthetic electric and magnetic fields. This study demonstrates the breakdown of detailed balance for the heat transfer function and the nonreciprocity induced by synthetic fields in graphene flakes and Casimir coupling between two objects. Synthetic fields also affect the mean occupation numbers of two membranes, which can be experimentally verified.