On some connections between first order irreversible thermodynamics and finite-time thermodynamics

被引：0

作者：

Angulo-Brown, F ^{[1
]}

Arias-Hernández, LA ^{[1
]}

Santillán, M ^{[1
]}

机构：

[1] Escuela Super Fis & Matemat, Inst Politecn Nacl, Dept Fis, Mexico City 07738, DF, Mexico

来源：

REVISTA MEXICANA DE FISICA | 2002年 / 48卷

关键词：

entropy production; power output; ecological function; thermal cycles; fluxes and forces; ATP-synthesis; muscle contraction;

D O I：

暂无

中图分类号：

O4 [物理学];

学科分类号：

0702 ;

摘要：

We present a brief review of some works addresed to a connection between concepts arising from both finite-time thermodynamics (FTT) and first order irreversible thermodynamics (FOIT). While the first order irreversible thermodynamics formalism is based on the study of local variables, finite time thermodynamics mainly deals with net global process variables. We show that it is possible to link the first order irreversible thermodynamics language of fluxes and forces with global thermodynamic quantities such as efficiency, power output and the so-called ecological function. This connection is illustrated with some biologically inspired problems.

引用

页码：182 / 192

页数：11

共 10 条

[1] Current Trends in Finite-Time Thermodynamics [J].

Andresen, Bjarne .

ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2011, 50 (12) :2690-2704

[2] Finite-Time Thermodynamics and the Optimal Control of Chemical Syntheses [J].

Schoen, J. Christian .

ZEITSCHRIFT FUR ANORGANISCHE UND ALLGEMEINE CHEMIE, 2009, 635 (12) :1794-1806

[3] Finite-Time Thermodynamics: Problems, Approaches, and Results [J].

Tsirlin, Anatoly M. ;

Balunov, Alexander I. ;

Sukin, Ivan A. .

ENTROPY, 2025, 27 (06)

[4] (Finite-Time) Thermodynamics, Hyperbolicity, Lorentz Invariance: Study of an Example [J].

Guy, Bernard .

ENTROPY, 2025, 27 (07)

[5] Performance Analysis of an Irreversible Otto Cycle using Finite Time Thermodynamics [J].

Mehta, Hemant B. ;

Bharti, Omprakash S. .

WORLD CONGRESS ON ENGINEERING 2009, VOLS I AND II, 2009, :1575-+

[6] Thermal cycles in classical thermodynamics and nonequilibrium thermodynamics in contrast with finite time thermodynamics [J].

Denton, JC .

ENERGY CONVERSION AND MANAGEMENT, 2002, 43 (13) :1583-1617

[7] Modeling, Simulation, and Reconstruction of 2-Reservoir Heat-to-Power Processes in Finite-Time Thermodynamics [J].

Muschik, Wolfgang ;

Hoffmann, Karl Heinz .

ENTROPY, 2020, 22 (09)

[8] Calorimetric Measurements of Biological Interactions and Their Relationships to Finite Time Thermodynamics Parameters [J].

Zhang, Yuwei ;

Kowalski, Gregory J. .

ENTROPY, 2022, 24 (04)

[9] Concepts of phenomenological irreversible quantum thermodynamics II: time dependent statistical ensembles of bipartite systems [J].

Muschik, Wolfgang .

JOURNAL OF NON-EQUILIBRIUM THERMODYNAMICS, 2023, 48 (04) :353-388

[10] Finite-time thermodynamic multi-objective optimizations for an irreversible simple Brayton refrigeration cycle based on four objectives, NASG-II algorithm and three decision-making strategies [J].

Wu, Bowen ;

Chen, Lingen ;

Ge, Yanlin ;

Feng, Huijun ;

Liu, Xu .

JOURNAL OF THERMAL ANALYSIS AND CALORIMETRY, 2025, 150 (06) :4653-4668

← 1 →