A general derivation and quantification of the third law of thermodynamics.

Type of article: Article

Summary

The most accepted version of the third law of thermodynamics, the unattainablility principle, states that any process cannot reach absolute zero temperature in a finite number of steps and within a finite time. Here, we provide a derivation of the principle that applies to arbitrary cooling processes, even those exploiting the laws of quantum mechanics or involving an infinite-dimensional reservoir. We quantify the resources needed to cool a system to any temperature, and translate these resources into the minimal time or number of steps, by considering the notion of a thermal machine that obeys similar restrictions to universal computers. We generally find that the obtainable temperature can scale as an inverse power of the cooling time. Our results also clarify the connection between two versions of the third law (the unattainability principle and the heat theorem), and place ultimate bounds on the speed at which information can be erased.

Details

Original title: A general derivation and quantification of the third law of thermodynamics.
Record ID : 30021143
Languages: English
Source: Nature Communications
Publication date: 2017/03/14
DOI: http://dx.doi.org/10.1038/ncomms14538

Links

See other articles in this issue (1)
See the source

Indexing

Themes: Thermodynamics, transfer processes: general information
Keywords: Thermodynamics; Cooling; Absolute zero; Modelling

We use cookies on this website to improve your user experience.
Your preferences can be changed at any time by clicking on « Manage services » at the bottom right of our pages.
To learn more, read our Privacy policy.