Related papers: Deriving the Landauer Principle From the Quantum Shannon Entropy

Deriving the Landauer Principle From the Quantum Shannon Entropy

URL: http://arxiv.org/abs/2410.05742v1
Date: Tue, 8 Oct 2024 07:01:37 GMT
Title: Deriving the Landauer Principle From the Quantum Shannon Entropy
Authors: Henrik J. Heelweg, Amro Dodin, Adam P. Willard,
Abstract summary: We derive an expression for the equilibrium probability distribution of a quantum state in contact with a noisy thermal environment. We show that the free energy required to erase or reset a qubit depends sensitively on both the fidelity of the target state and on the physical properties of the environment.
Score: 0.0
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: We derive an expression for the equilibrium probability distribution of a quantum state in contact with a noisy thermal environment that formally separates contributions from quantum and classical forms of probabilistic uncertainty. A statistical mechanical interpretation of this probability distribution enables us to derive an expression for the minimum free energy costs for arbitrary (reversible or irreversible) quantum state changes. Based on this derivation, we demonstrate that - in contrast to classical systems - the free energy required to erase or reset a qubit depends sensitively on both the fidelity of the target state and on the physical properties of the environment, such as the number of quantum bath states, due primarily to the entropic effects of system-bath entanglement.

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