Optimization and Stability of Heat Engines: The Role of Entropy Evolution

Optimization and Stability of Heat Engines: The Role of Entropy Evolution

Local stability of maximum power and maximum compromise (Omega) operation regimes dynamic evolution for a low-dissipation heat engine is analyzed. The thermodynamic behavior of trajectories to the stationary state, after perturbing the operation regime, display a trade-off between stability, entropy...

Full description

Bibliographic Details
Main Authors: Julian Gonzalez-Ayala, Moises Santillán, Maria Jesus Santos, Antonio Calvo Hernández, José Miguel Mateos Roco
Format: Article
Language:English
Published: MDPI AG 2018-11-01
Series:Entropy
Subjects:
heat engine
local stability
maximum power regime
maximum Omega regime
entropy production
Online Access:https://www.mdpi.com/1099-4300/20/11/865
id doaj-7d4e7665e90b42a28b5072831ae3e913
record_format Article
spelling doaj-7d4e7665e90b42a28b5072831ae3e9132020-11-24T20:59:13ZengMDPI AGEntropy1099-43002018-11-01201186510.3390/e20110865e20110865Optimization and Stability of Heat Engines: The Role of Entropy EvolutionJulian Gonzalez-Ayala0Moises Santillán1Maria Jesus Santos2Antonio Calvo Hernández3José Miguel Mateos Roco4Departamento de Física Aplicada, Universidad de Salamanca, 37008 Salamanca, SpainCentro de Investigación y Estudios Avanzados del IPN Unidad Monterrey, Apodaca, NL 66600, MexicoDepartamento de Física Aplicada, Universidad de Salamanca, 37008 Salamanca, SpainDepartamento de Física Aplicada, Universidad de Salamanca, 37008 Salamanca, SpainDepartamento de Física Aplicada, Universidad de Salamanca, 37008 Salamanca, SpainLocal stability of maximum power and maximum compromise (Omega) operation regimes dynamic evolution for a low-dissipation heat engine is analyzed. The thermodynamic behavior of trajectories to the stationary state, after perturbing the operation regime, display a trade-off between stability, entropy production, efficiency and power output. This allows considering stability and optimization as connected pieces of a single phenomenon. Trajectories inside the basin of attraction display the smallest entropy drops. Additionally, it was found that time constraints, related with irreversible and endoreversible behaviors, influence the thermodynamic evolution of relaxation trajectories. The behavior of the evolution in terms of the symmetries of the model and the applied thermal gradients was analyzed.https://www.mdpi.com/1099-4300/20/11/865heat enginelocal stabilitymaximum power regimemaximum Omega regimeentropy production
collection DOAJ
language English
format Article
sources DOAJ
author Julian Gonzalez-Ayala
Moises Santillán
Maria Jesus Santos
Antonio Calvo Hernández
José Miguel Mateos Roco
spellingShingle Julian Gonzalez-Ayala
Moises Santillán
Maria Jesus Santos
Antonio Calvo Hernández
José Miguel Mateos Roco
Optimization and Stability of Heat Engines: The Role of Entropy Evolution
Entropy
heat engine
local stability
maximum power regime
maximum Omega regime
entropy production
author_facet Julian Gonzalez-Ayala
Moises Santillán
Maria Jesus Santos
Antonio Calvo Hernández
José Miguel Mateos Roco
author_sort Julian Gonzalez-Ayala
title Optimization and Stability of Heat Engines: The Role of Entropy Evolution
title_short Optimization and Stability of Heat Engines: The Role of Entropy Evolution
title_full Optimization and Stability of Heat Engines: The Role of Entropy Evolution
title_fullStr Optimization and Stability of Heat Engines: The Role of Entropy Evolution
title_full_unstemmed Optimization and Stability of Heat Engines: The Role of Entropy Evolution
title_sort optimization and stability of heat engines: the role of entropy evolution
publisher MDPI AG
series Entropy
issn 1099-4300
publishDate 2018-11-01
description Local stability of maximum power and maximum compromise (Omega) operation regimes dynamic evolution for a low-dissipation heat engine is analyzed. The thermodynamic behavior of trajectories to the stationary state, after perturbing the operation regime, display a trade-off between stability, entropy production, efficiency and power output. This allows considering stability and optimization as connected pieces of a single phenomenon. Trajectories inside the basin of attraction display the smallest entropy drops. Additionally, it was found that time constraints, related with irreversible and endoreversible behaviors, influence the thermodynamic evolution of relaxation trajectories. The behavior of the evolution in terms of the symmetries of the model and the applied thermal gradients was analyzed.
topic heat engine
local stability
maximum power regime
maximum Omega regime
entropy production
url https://www.mdpi.com/1099-4300/20/11/865
work_keys_str_mv AT juliangonzalezayala optimizationandstabilityofheatenginestheroleofentropyevolution
AT moisessantillan optimizationandstabilityofheatenginestheroleofentropyevolution
AT mariajesussantos optimizationandstabilityofheatenginestheroleofentropyevolution
AT antoniocalvohernandez optimizationandstabilityofheatenginestheroleofentropyevolution
AT josemiguelmateosroco optimizationandstabilityofheatenginestheroleofentropyevolution
_version_ 1716783260013428736

Similar Items