Download .BibTex - 1.1 KB
Download .PDF - 551 KB
PhysRevLett.122.040602-2.pdf
Download .PDF - 198.3 KB
supplemental.pdf
Abstract

Landauer’s erasure principle states that the irreversible erasure of a one-bit memory, embedded in a thermal environment, is accompanied with a work input of at least k_BTln2. Fundamental to that principle is the assumption that the physical states representing the two possible logical states are close to thermal equilibrium. Here, we propose and theoretically analyze a minimalist mechanical model of a one-bit memory operating with squeezed thermal states. It is shown that the Landauer energy bound is exponentially lowered with increasing squeezing factor. Squeezed thermal states, which may naturally arise in digital electronic circuits operating in a pulse-driven fashion, thus can be exploited to reduce the fundamental energy costs of an erasure operation.
URL

https://doi.org/10.1103/PhysRevLett.122.040602
Authors

J. Klaers
Year of publication

2019
Date published

01/2019
Journal

Phys. Rev. Lett.
Volume

122
Pages

040602: 1-5
DOI number

https://doi.org/10.1103/PhysRevLett.122.040602

More publications

Article
Non-utopian optical properties computed of a tomographically reconstructed real photonic nanostructure
L. J. Corbijn van Willenswaard, S. Smeets, N. Renaud, M. Schlottbom, J. J. W. van der Vegt, and W. L. Vos
Article
Probing the Position-Dependent Optical Energy Fluence Rate in 3D Scattering Samples
O. Akdemir, M. D. Truong, A. Rates, A. Lagendijk, and W. L. Vos
Article
Strongly inhibited spontaneous emission of PbS quantum dots covalently bound to 3D silicon photonic band gap crystals
A. S. Schulz, M. Kozoň, G. J. Vancso, J. Huskens, and W. L. Vos
More publications