Nanoelectronics «bottom – up»: thermodynamics of electric conductor, information-driven battery and quantum entropy

Authors

  • Юрий Алексеевич Кругляк Odessa State Environmental University 15 Lvovskaya str., Odessa, Ukraine, 65016, Ukraine

DOI:

https://doi.org/10.15587/2313-8416.2015.53495

Keywords:

nanophysics, nanoelectronics, resistor thermodynamics, information storage, Landauer principleб quantum entropy

Abstract

Within the «bottom – up» approach of nanoelectronics the equilibrium thermodynamics of a conductor with a current is presented and the accumulation of information in a non-equilibrium state with an analysis of information-driven battery model is discussed in connection with the Landauer principle on the minimum of energy needed to erase one bit of information. The concept of quantum entropy is introduced and the importance of integration of spintronics and magnetronics in connection with the upcoming development of the spin architecture for the computing devices are discussed

Author Biography

Юрий Алексеевич Кругляк, Odessa State Environmental University 15 Lvovskaya str., Odessa, Ukraine, 65016

Doctor of Chemical Sciences, Professor

Department of Information Technologies

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Published

2015-11-23

Issue

Section

Physics and mathematics