Large work extraction and the Landauer limit in a continuous Maxwell demon

TL;DR

This paper introduces the Continuous Maxwell Demon (CMD), a device that extracts work from a system by repeated measurements, demonstrating its limits and efficiency in DNA hairpin experiments, and confirming the theoretical link to the Landauer limit.

Contribution

The paper presents the concept and experimental validation of the Continuous Maxwell Demon, extending classical ideas to continuous measurements and linking work extraction to information content.

Findings

Maximum work per cycle is limited by information content.

Work extraction efficiency peaks with high information content.

Experimental validation with DNA hairpin pulling experiments.

Abstract

The relation between entropy and information dates back to the classical Maxwell demon (MD) paradox, a thought experiment proposed in 1867 by J. C. Maxwell to violate the second law of thermodynamics. A variant of the classical MD is the Szilard engine proposed by L. Szilard in 1926 in which the demon observes, at a given time, the compartment occupied by a single molecule in a vessel and extracts work by operating a pulley device. Here we introduce the Continuous Maxwell Demon (CMD), a device capable of extracting arbitrarily large amounts of work per cycle by repeated measurements of the state of a system, and experimentally test it in single DNA hairpin pulling experiments. In the CMD the demon monitors the state of the DNA hairpin (folded or unfolded) by observing it at equally spaced time intervals but extracts work only when the molecule changes state. We demonstrate that the average maximum work per cycle that can be extracted by the CMD is limited by the information-content of the stored sequences, in agreement with the second law. Work extraction efficiency is found to be maximal in the large information-content limit where work extraction is fuelled by rare events.