Quantifying memory capacity as a quantum thermodynamic resource
Abstract
The information-carrying capacity of a memory is known to be a thermodynamic resource facilitating the conversion of heat to work. Szilard's engine explicates this connection through a toy example involving an energy-degenerate two-state memory. We devise a formalism to quantify the thermodynamic value of memory in general quantum systems with nontrivial energy landscapes. Calling this the thermal information capacity, we show that it converges to the non-equilibrium Helmholtz free energy in the thermodynamic limit. We compute the capacity exactly for a general two-state (qubit) memory away from the thermodynamic limit, and find it to be distinct from known free energies. We outline an explicit memory--bath coupling that can approximate the optimal qubit thermal information capacity arbitrarily well.
Cite
@article{arxiv.1806.00025,
title = {Quantifying memory capacity as a quantum thermodynamic resource},
author = {Varun Narasimhachar and Jayne Thompson and Jiajun Ma and Gilad Gour and Mile Gu},
journal= {arXiv preprint arXiv:1806.00025},
year = {2019}
}
Comments
6 main + 7 appendix pages; 5 main + 2 appendix figures