The role of the Stefan-Boltzmann law in the thermodynamic optimization of an n-Müser engine

M. A. Ramírez-Moreno; S. González-Hernández; F. Angulo-Brown

doi:10.1016/j.physa.2015.10.094

The role of the Stefan-Boltzmann law in the thermodynamic optimization of an n-Müser engine

M. A. Ramírez-Moreno, S. González-Hernández, F. Angulo-Brown

Research output: Contribution to journal › Article › peer-review

18 Scopus citations

Abstract

A Müser-type engine model can be taken as a particular case of a Curzon-Ahlborn thermal cycle, when the upper thermal conductance is finite and the lower one is infinite. In addition, the upper heat exchange is given by the Stefan-Boltzmann law. That model is suitable to thermodynamically describe some aspects of energy converters as solar cells and photosynthetic systems. In the present article, we call n-Müser engine to an engine of the Müser type in which the ^T4 heat transfer law is substituted by a ^Tn-law, being n>0 a real number. Here, we show that if we use the so-called ecological criterion of merit to optimize finite-time heat engines to compare the thermodynamic performance of the n-Müser engines under approximate terrestrial conditions (see below), we obtain that n=4 accomplishes the best performance. This same result was obtained by using data from the rest of planets of the solar system.

Original language	English
Pages (from-to)	914-921
Number of pages	8
Journal	Physica A: Statistical Mechanics and its Applications
Volume	444
DOIs	https://doi.org/10.1016/j.physa.2015.10.094
State	Published - 15 Feb 2016
Externally published	Yes

Keywords

Blackbody radiation
Curzon-Ahlborn engine
Heat transfer law
Müser engine

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title = "The role of the Stefan-Boltzmann law in the thermodynamic optimization of an n-M{\"u}ser engine",

abstract = "A M{\"u}ser-type engine model can be taken as a particular case of a Curzon-Ahlborn thermal cycle, when the upper thermal conductance is finite and the lower one is infinite. In addition, the upper heat exchange is given by the Stefan-Boltzmann law. That model is suitable to thermodynamically describe some aspects of energy converters as solar cells and photosynthetic systems. In the present article, we call n-M{\"u}ser engine to an engine of the M{\"u}ser type in which the T4 heat transfer law is substituted by a Tn-law, being n>0 a real number. Here, we show that if we use the so-called ecological criterion of merit to optimize finite-time heat engines to compare the thermodynamic performance of the n-M{\"u}ser engines under approximate terrestrial conditions (see below), we obtain that n=4 accomplishes the best performance. This same result was obtained by using data from the rest of planets of the solar system.",

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AU - González-Hernández, S.

AU - Angulo-Brown, F.

PY - 2016/2/15

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AB - A Müser-type engine model can be taken as a particular case of a Curzon-Ahlborn thermal cycle, when the upper thermal conductance is finite and the lower one is infinite. In addition, the upper heat exchange is given by the Stefan-Boltzmann law. That model is suitable to thermodynamically describe some aspects of energy converters as solar cells and photosynthetic systems. In the present article, we call n-Müser engine to an engine of the Müser type in which the T4 heat transfer law is substituted by a Tn-law, being n>0 a real number. Here, we show that if we use the so-called ecological criterion of merit to optimize finite-time heat engines to compare the thermodynamic performance of the n-Müser engines under approximate terrestrial conditions (see below), we obtain that n=4 accomplishes the best performance. This same result was obtained by using data from the rest of planets of the solar system.

KW - Blackbody radiation

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JO - Physica A: Statistical Mechanics and its Applications

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ER -

The role of the Stefan-Boltzmann law in the thermodynamic optimization of an n-Müser engine

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Keywords

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