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Physics Maths Engineering

A Thermodynamic Measure of Sustainability

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Enrico Sciubba

Enrico Sciubba


  Peer Reviewed

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© attribution CC-BY

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Added on

2024-10-26

Doi: http://dx.doi.org/10.3389/frsus.2021.739395

Related Subjects
Physics
Math
Chemistry
Computer science
Engineering
Earth science
Biology

Abstract

A novel thermodynamic approach to the quantification of the “degree of sustainability” is proposed and discussed. The method includes a rigorous -and innovative- conversion procedure of the so-called externalities that leads to their expression in terms of the exergy of their equivalent primary resources consumption. Such a thermodynamic approach suggests a detailed re-evaluation of the concept of sustainability because it is well-known that the Second Law strictly negates the possibility for any open and evolving system to maintain itself in a “sustainable” state without availing itself of a continuous supply of low-entropy (i.e., high specific exergy) input. If a human society is modeled as an open system, its capacity to “grow sustainably” depends not only on how it uses non-renewable resources, but also on the rate at which it exploits the renewable ones. The necessary inclusion of different forms of energy- and material flows in such an analysis constitutes per se an argument in favor of a resource-based exergy metrics. While it is true that the thermodynamically oriented approach proposed here neglects all of the non-thermodynamic attributes of a “sustainable system” (in the Bruntland sense), it is also clear that it constitutes a rigorous basis on which different physically possible scenarios can be rigorously evaluated. Non-thermodynamic indicators can be still used at a “second level analysis” and maintain their usefulness to indicate which one of the “thermodynamically least unsustainable” scenarios is most convenient from an ethical or socio-economic perspective for the considered community or for the society as a whole. The proposed indicator is known as “Exergy Footprint,” and the advantages of its systematic application to the identification of “sustainable growth paths” is discussed in the Conclusions.

Key Questions about Thermodynamic Sustainability Measures

The article "A Thermodynamic Measure of Sustainability" by Enrico Sciubba introduces a novel thermodynamic approach to quantifying the "degree of sustainability." This method involves converting externalities into terms of exergy—the measure of energy quality—equivalent to primary resource consumption. Sciubba argues that, according to the Second Law of Thermodynamics, any open and evolving system requires a continuous supply of low-entropy (high specific exergy) input to maintain a sustainable state. Therefore, a society's capacity for sustainable growth depends not only on how it uses non-renewable resources but also on the rate at which it exploits renewable ones. The study emphasizes the importance of including various forms of energy and material flows in sustainability analyses, advocating for a resource-based exergy metric to evaluate sustainable growth paths. ([frontiersin.org](https://www.frontiersin.org/journals/sustainability/articles/10.3389/frsus.2021.739395/full))

1. How can sustainability be quantified thermodynamically?

The article proposes a method that converts externalities into exergy terms, providing a thermodynamic measure of sustainability. ([frontiersin.org](https://www.frontiersin.org/journals/sustainability/articles/10.3389/frsus.2021.739395/full))

2. What role does exergy play in sustainable growth?

Exergy is essential for maintaining a sustainable state in open systems, as it represents the quality of energy required for growth and development. ([frontiersin.org](https://www.frontiersin.org/journals/sustainability/articles/10.3389/frsus.2021.739395/full))

3. How does the Second Law of Thermodynamics relate to sustainability?

The Second Law implies that systems cannot maintain a sustainable state without a continuous supply of low-entropy input, highlighting the need for efficient energy use. ([frontiersin.org](https://www.frontiersin.org/journals/sustainability/articles/10.3389/frsus.2021.739395/full))

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ARTICLE USAGE


Article usage: Oct-2024 to May-2025
Show by month Manuscript Video Summary
2025 May 67 67
2025 April 67 67
2025 March 59 59
2025 February 52 52
2025 January 48 48
2024 December 54 54
2024 November 50 50
2024 October 16 16
Total 413 413
Show by month Manuscript Video Summary
2025 May 67 67
2025 April 67 67
2025 March 59 59
2025 February 52 52
2025 January 48 48
2024 December 54 54
2024 November 50 50
2024 October 16 16
Total 413 413
Related Subjects
Physics
Math
Chemistry
Computer science
Engineering
Earth science
Biology
copyright icon

© attribution CC-BY

  • 0

rating
413 Views

Added on

2024-10-26

Doi: http://dx.doi.org/10.3389/frsus.2021.739395

Related Subjects
Physics
Math
Chemistry
Computer science
Engineering
Earth science
Biology

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