Positive and negative entropy production in an ideal-gas expansion

A modified expression of the electron entropy production in a plasma is deduced by means of the Kelly equations of state instead of the ideal gas equations of state. From the Debye–Hückel model which considers the interaction between the charges, such equations of state are derived for a plasma and the entropy is deduced. The technique to obtain the modified entropy production is based on usual developments but including the modified equations of state giving the regular result plus some extra terms. We derive an expression of the modified entropy production in terms of the tensorial Hermitian moments hr1…rm(m) by means of the irreducible tensorial Hermite polynomials.

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Negative entropy-production rate in Rayleigh-Bénard convection in two-dimensional Yukawa liquids

Physical Review E ◽

10.1103/physreve.100.053201 ◽

2019 ◽

Vol 100 (5) ◽

Author(s):

Pawandeep Kaur ◽

Rajaraman Ganesh

Keyword(s):

Entropy Production ◽

Production Rate ◽

Entropy Production Rate ◽

Two Dimensional ◽

Negative Entropy ◽

Bénard Convection ◽

Benard Convection ◽

Rayleigh Benard Convection ◽

Rayleigh Benard

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Modeling of Entropy Production in Turbulent Flows

Journal of Fluids Engineering ◽

10.1115/1.1845551 ◽

2004 ◽

Vol 126 (6) ◽

pp. 893-899 ◽

Cited By ~ 39

Author(s):

O. B. Adeyinka ◽

G. F. Naterer

Keyword(s):

Entropy Production ◽

Turbulent Flows ◽

Incompressible Flows ◽

Momentum Equation ◽

Ideal Gas ◽

Equation Modeling ◽

Mean Flow ◽

Ideal Gas Law ◽

Empirical Relations ◽

Entropy Transport

This article presents new modeling of turbulence correlations in the entropy transport equation for viscous, incompressible flows. An explicit entropy equation of state is developed for gases with the ideal gas law, while entropy transport equations are derived for both gases and liquids. The formulation specifically considers incompressible forced convection problems without a buoyancy term in the y-momentum equation, as density variations are neglected. Reynolds averaging techniques are applied to the turbulence closure of fluctuating temperature and entropy fields. The problem of rigorously expressing the mean entropy production in terms of other mean flow quantities is addressed. The validity of the newly developed formulation is assessed using direct numerical simulation data and empirical relations for the friction factor. Also, the dissipation (ε) of turbulent kinetic energy is formulated in terms of the Second Law. In contrast to the conventional ε equation modeling, this article proposes an alternative method by utilizing both transport and positive definite forms of the entropy production equation.

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Negative entropy production in oscillatory processes

Comptes Rendus Physique ◽

10.1016/j.crhy.2007.05.007 ◽

2007 ◽

Vol 8 (5-6) ◽

pp. 620-624 ◽

Cited By ~ 7

Author(s):

Stephen R. Williams ◽

Denis J. Evans ◽

Emil Mittag

Keyword(s):

Entropy Production ◽

Negative Entropy ◽

Oscillatory Processes

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A note on acoustic turbulence

Journal of Fluid Mechanics ◽

10.1017/jfm.2019.523 ◽

2019 ◽

Vol 874 ◽

Cited By ~ 2

Author(s):

Erik Lindborg

Keyword(s):

Structure Function ◽

Entropy Production ◽

Acoustic Field ◽

Three Dimensional ◽

Weak Shock ◽

Separation Distance ◽

Ideal Gas ◽

Order Structure ◽

Specific Heats ◽

The Mean

We consider a three-dimensional acoustic field of an ideal gas in which all entropy production is confined to weak shocks and show that similar scaling relations hold for such a field as for forced Burgers turbulence, where the shock amplitude scales as $(\unicode[STIX]{x1D716}d)^{1/3}$ and the $p$th-order structure function scales as $(\unicode[STIX]{x1D716}d)^{p/3}r/d$, $\unicode[STIX]{x1D716}$ being the mean energy dissipation per unit mass, $d$ the mean distance between the shocks and $r$ the separation distance. However, for the acoustic field, $\unicode[STIX]{x1D716}$ should be replaced by $\unicode[STIX]{x1D716}+\unicode[STIX]{x1D712}$, where $\unicode[STIX]{x1D712}$ is associated with entropy production due to heat conduction. In particular, the third-order longitudinal structure function scales as $\langle \unicode[STIX]{x1D6FF}u_{r}^{3}\rangle =-C(\unicode[STIX]{x1D716}+\unicode[STIX]{x1D712})r$, where $C$ takes the value $12/5(\unicode[STIX]{x1D6FE}+1)$ in the weak shock limit, $\unicode[STIX]{x1D6FE}=c_{p}/c_{v}$ being the ratio between the specific heats at constant pressure and constant volume.

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A xenon power cycle and the second law of thermodynamics

Physics Essays ◽

10.4006/0836-1398-32.3.394 ◽

2019 ◽

Vol 32 (3) ◽

pp. 394-398

Author(s):

David Van Den Einde

Keyword(s):

Enthalpy Of Solution ◽

Excess Enthalpy ◽

Second Law Of Thermodynamics ◽

Ideal Gas ◽

Working Fluid ◽

Power Cycle ◽

Exhaust Heat ◽

Heat Regeneration ◽

Gas Expansion ◽

Dense Liquid

Xenon plus a molecular solid solute that yields a positive excess enthalpy of solution reaction form the working fluid for a transcritical power cycle. Xenon exhibits large changes in induced polarities with the change in density in the temperature and pressure range of the cycle described. A difference in excess enthalpy of solution between the reaction in xenon’s dense liquid state and expanded supercritical fluid state affects the cycle’s efficiency by internally elevating the temperature of heat input from near the cycle’s T2 to near its T1 before that energy affects gas expansion. This positive excess enthalpy differential establishes conditions in the cycle that allows for complete exhaust heat regeneration. The energy transfer invalidates Carnot’s and Clausius’s original assumption that the rate an ideal gas can convert heat energy to work by its expansion and contraction establishes heat as the lowest form of energy to which all other forms degrade.

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Fluctuation theorem for entropy production during effusion of a relativistic ideal gas

Physical Review E ◽

10.1103/physreve.77.022103 ◽

2008 ◽

Vol 77 (2) ◽

Cited By ~ 6

Author(s):

B. Cleuren ◽

K. Willaert ◽

A. Engel ◽

C. Van den Broeck

Keyword(s):

Entropy Production ◽

Ideal Gas ◽

Fluctuation Theorem

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Analysis of Space Shuttle External Tank Spray-On Foam Insulation With Internal Pore Pressure

Journal of Engineering Materials and Technology ◽

10.1115/1.2969247 ◽

2008 ◽

Vol 130 (4) ◽

Cited By ~ 6

Author(s):

Brett A. Bednarcyk ◽

Jacob Aboudi ◽

Steven M. Arnold ◽

Roy M. Sullivan

Keyword(s):

Pore Pressure ◽

Polymer Material ◽

Space Shuttle ◽

Micromechanical Model ◽

Constitutive Models ◽

Ideal Gas ◽

Material Creep ◽

Parametric Studies ◽

Gas Expansion ◽

Internal Pore

The polymer spray-on foam insulation used on NASA’s Space Shuttle external fuel tank is analyzed via the high-fidelity generalized method of cells micromechanical model. This model has been enhanced to include internal pore pressure, which is applied as a boundary condition on the internal faces of the foam pores. The pore pressure arises due to both ideal gas expansion during a temperature change as well as outgassing of species from the foam polymer material. Material creep and elastic stiffening are also incorporated via appropriate constitutive models. Due to the lack of reliable properties for the in situ foam polymer material, these parameters are backed out from foam thermomechanical test data. Parametric studies of the effects of key variables (both property-related and microstructural) are presented as is a comparison of model predictions for the thermal expansion behavior of the foam with experimental data.

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