Search results for "Thermodynamic system"

showing 10 items of 10 documents

Basic Notions of the Theory of Heat

2016

This chapter summarizes some basic notions of thermodynamics and defines the empirical variables which are needed for the description of thermodynamic systems in equilibrium. Empirical temperature and several scales used to measure temperature are defined. The so-called “zeroth law of thermodynamics” is formulated which says that systems which are in mutual equilibrium have the same temperature. Thermodynamic ensembles corresponding to different macroscopic boundary conditions are introduced and are illustrated by simple models such as the ideal gas. Also, entropy appears on the scene for a first time, both in its statistical and its thermodynamical interpretation. Gibb’s fundamental form i…

Canonical ensembleTheoretical physicsEntropy (classical thermodynamics)Grand canonical ensembleZeroth law of thermodynamicsTheory of heatBoundary value problemThermodynamic systemIdeal gasMathematics
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Thermodynamics of a Phase-Driven Proximity Josephson Junction

2019

We study the thermodynamic properties of a superconductor/normal metal/superconductor Josephson junction {in the short limit}. Owing to the proximity effect, such a junction constitutes a thermodynamic system where {phase difference}, supercurrent, temperature and entropy are thermodynamical variables connected by equations of state. These allow conceiving quasi-static processes that we characterize in terms of heat and work exchanged. Finally, we combine such processes to construct a Josephson-based Otto and Stirling cycles. We study the related performance in both engine and refrigerator operating mode.

Josephson effectsns junctionStirling enginesuprajohtavuusGeneral Physics and Astronomy02 engineering and technology01 natural sciences7. Clean energysuprajohteetlaw.inventionlawJosephson junctionMaxwell relationCondensed Matter::Superconductivityquasi-particles entropykvanttifysiikkalcsh:Scienceproximity effect; superconductivity; Josephson junction; SNS junction; Josephson thermodynamics; Maxwell relation; quasi-particles entropy; quantum thermodynamics; quantum machines; quantum coolersPhysicsSuperconductivityQuantum PhysicsCondensed matter physicssuperconductivitySupercurrent021001 nanoscience & nanotechnologyThermodynamic systemlcsh:QC1-999termodynamiikkaproximity effectjosephson thermodynamics0210 nano-technologyRefrigerator carFOS: Physical sciencesJosephson thermodynamicslcsh:AstrophysicsArticleSuperconductivity (cond-mat.supr-con)Entropy (classical thermodynamics)quantum coolers0103 physical sciencesMesoscale and Nanoscale Physics (cond-mat.mes-hall)lcsh:QB460-466010306 general physicsquantum machinesPhase differenceCondensed Matter - Mesoscale and Nanoscale PhysicsCondensed Matter - SuperconductivitySNS junctionjosephson junctionmaxwell relationquantum thermodynamicslcsh:QQuantum Physics (quant-ph)lcsh:PhysicsEntropy
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Interface thermodynamic model for low pressure evaporation

1979

Materials scienceInterface (Java)[SPI] Engineering Sciences [physics]EvaporationGeneral Physics and AstronomyThermodynamics02 engineering and technologyGeneral ChemistryThermodynamic databases for pure substances[SPI.FLUID] Engineering Sciences [physics]/Reactive fluid environment021001 nanoscience & nanotechnology01 natural sciencesThermodynamic system010406 physical chemistry0104 chemical sciencesThermodynamic modelThermodynamic diagrams0210 nano-technologyMaterial propertiesThermodynamic process
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Fractional-Order Thermal Energy Transport for Small-Scale Engineering Devices

2014

Fractional-order thermodynamics has proved to be an efficient tool to describe several small-scale and/or high-frequency thermodynamic processes, as shown in many engineering and physics applications. The main idea beyond fractional-order physics and engineering relies on replacing the integer-order operators of classical differential calculus with their real-order counterparts. In this study, the authors aim to extend a recently proposed physical picture of fractional-order thermodynamics to a generic 3D rigid heat conductor where the thermal energy transfer is due to two phenomena: a short-range heat flux ruled by stationary and nonstationary transport equations, and a long-range thermal …

PhysicsFundamental thermodynamic relationbusiness.industryMechanical EngineeringNon-equilibrium thermodynamicsThermodynamic equationsThermodynamic systemThermodynamic free energyLong-range energy transport Fractional calculus Phonons transport Fractional heat transfer Kapitza effectStatistical physicsSettore ICAR/08 - Scienza Delle CostruzionibusinessTransport phenomenaThermal energyThermodynamic processJournal of Nanomechanics and Micromechanics
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XVII.Thermodynamic principle governing stationary states

1933

(1933). XVII. Thermodynamic principle governing stationary states. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science: Vol. 16, No. 104, pp. 248-263.

PhysicsThermodynamicsThermodynamic equationsThermodynamic systemStationary stateMathematical physicsThe London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science
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Models for highway traffic and their connections to thermodynamics

2007

Models for highway traffic are studied by numerical simulations. Of special interest is the spontaneous formation of traffic jams. In a thermodynamic system the traffic jam would correspond to the dense phase (liquid) and the free flowing traffic would correspond to the gas phase. Both phases depending on the density of cars can be present at the same time. A model for a single lane circular road has been studied. The model is called the optimal velocity model (OVM) and was developed by Bando, Sugiyama, et al. We propose here a reformulation of the OVM into a description in terms of potential energy functions forming a kind of Hamiltonian for the system. This will however not be a globally …

Physicssymbols.namesakeOther Physics TopicsMonte Carlo methodsymbolsIsing modelAnnan fysikStatistical physicsHamiltonian (quantum mechanics)Potential energyThermodynamic systemGas phase
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Gibbs equation in the nonlinear nonequilibrium thermodynamics of dilute nonviscous gases

2003

AbstractThis paper deals with the derivation of the Gibbs equation for a nonviscous gas in the presence of heat flux. The analysis aims to shed some light on the physical interpretation of thermodynamic potentials far from equilibrium. Two different definitions for the chemical potential and thermodynamic pressure far from equilibrium are introduced: nonequilibrium chemical potential and nonequilibrium thermodynamic pressure at constant heat flux q and nonequilibrium chemical potential and nonequilibrium thermodynamic pressure at constant J = Vq, where V is the specific volume.

Thermodynamic stateThermodynamic equilibriumApplied MathematicsNonequilibrium thermodynamic potentialsThermodynamicsThermodynamic databases for pure substancesNonequilibrium thermodynamicsThermodynamic equationsThermodynamic systemExtended thermodynamicsThermodynamic potentialsymbols.namesakeGibbs equationGibbs–Helmholtz equationsymbolsKinetic theoryMathematicsThermodynamic processApplied Mathematics Letters
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Criteria for validity of thermodynamic equations from non-equilibrium molecular dynamics simulations

2008

Abstract The assumption of local equilibrium is validated in four different systems where heat and mass are transported. Mass fluxes up to 13 kmol / m 2 s and temperature gradients up to 10 12 K / m were used. A two-component mixture, two vapor–liquid interfaces, a chemical reaction in a temperature gradient and gas adsorbed in zeolite were studied using non-equilibrium molecular dynamics simulations. In all cases, we verified that thermodynamic variables obeyed normal thermodynamic relations, with an accuracy better than 5%. The heat and mass fluxes, and the reaction rate were linearly related to the driving forces. Onsager's reciprocal relations were validated for two systems. Equipartiti…

Thermodynamic stateThermodynamic equilibriumChemistryMechanical EngineeringThermodynamicsBuilding and ConstructionThermodynamic equationsPollutionThermodynamic systemMaxwell–Boltzmann distributionBoltzmann equationIndustrial and Manufacturing EngineeringThermodynamic squaresymbols.namesakeGeneral EnergysymbolsElectrical and Electronic EngineeringCivil and Structural EngineeringThermodynamic processEnergy
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Thermodynamics of small systems embedded in a reservoir: a detailed analysis of finite size effects

2012

International audience; We present a detailed study on the finite size scaling behaviour of thermodynamic properties for small systems of particles embedded in a reservoir. Previously, we derived that the leading finite size effects of thermodynamic properties for small systems scale with the inverse of the linear length of the small system, and we showed how this can be used to describe systems in the thermodynamic limit [Chem. Phys. Lett. 504, 199 (2011)]. This approach takes into account an effective surface energy, as a result of the non-periodic boundaries of the small embedded system. Deviations from the linear behaviour occur when the small system becomes very small, i.e. smaller tha…

Work (thermodynamics)Scale (ratio)ChemistryBiophysicsThermodynamicsInverse02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesThermodynamic systemNANOTHERMODYNAMICS0104 chemical sciencesThermodynamic limitStatistical physicsPhysical and Theoretical Chemistry0210 nano-technologyMolecular BiologyScalingEnergy (signal processing)Order of magnitudeMolecular Physics
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Thermodynamics: Classical Framework

2016

This chapter starts with a summary of the thermodynamic potentials and the relationships between them which are obtained from Legendre transformation. This is followed by an excursion to some important global properties of materials such as specific heat, expansion coefficients and others. The thermodynamic relations provide the basis for a discussion of continuous changes of state which are illustrated by the Joule-Thomson effect and the Van der Waals gas. These are models which are more realistic than the ideal gas. The discussion of Carnot cycles leads to and illustrates the second and third laws of thermodynamics. The chapter closes with a discussion of entropy as a concave function of …

symbols.namesakeEntropy (classical thermodynamics)Fundamental thermodynamic relationOn the Equilibrium of Heterogeneous SubstancessymbolsNon-equilibrium thermodynamicsStatistical physicsCarnot cycleThermodynamic systemLaws of thermodynamicsThermodynamic potentialMathematics
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