Search results for "Maxwell relation"

showing 5 items of 5 documents

Direct and indirect determination of electrocaloric effect in Na0.5Bi0.5TiO3

2017

This work has been supported by the National Research Program in the framework of the project “Multifunctional Materials and composites, photonics and nanotechnology (IMIS2).”

010302 applied physicsMaterials scienceCondensed matter physicsAnalytical chemistryGeneral Physics and Astronomy02 engineering and technology021001 nanoscience & nanotechnologyPolarization (waves)01 natural sciencesElectric field0103 physical sciencesElectrocaloric effect:NATURAL SCIENCES:Physics [Research Subject Categories]PolarMaxwell relations0210 nano-technology
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Electrocaloric Effect in (1−x)(0.8Na0.5Bi0.5TiO3-0.2BaTiO3)−xCaTiO3 Solid Solutions at High Electric Fields

2022

This research was funded by the Latvian Science Council Fund, grant number lzp-2020/2-0080. The Institute of Solid State Physics, University of Latvia as the Center of Excellence has received funding from the European Union’s Horizon 2020 Framework Programme, grant number 739508.

Inorganic ChemistryElectrocaloric effectPhase transitionsMaxwell relationGeneral Chemical Engineering:NATURAL SCIENCES [Research Subject Categories]Dielectric polarizationGeneral Materials ScienceSodium bismuth titanateCondensed Matter Physicssodium bismuth titanate; solid solutions; electrocaloric effect; dielectric polarization; phase transitions; Maxwell relationSolid solutionsCrystals
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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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Symmetries and Covariance of the Maxwell Equations

2012

Already within a given, fixed division of four-dimensional spacetime into the space where experiments are performed, and the laboratory time variable, Maxwell’s equations show interesting transformation properties under continuous and discrete space-time transformations. However, only the action of the whole Lorentz group on them reveals their full symmetry structure. A good example that illustrates the covariance of Maxwell’s equations is provided by the electromagnetic fields of a point charge uniformly moving along a straight line.

Lorentz groupElectromagnetic fieldPhysicssymbols.namesakeMathematical optimizationClassical mechanicsSpacetimeMaxwell's equationssymbolsInhomogeneous electromagnetic wave equationMaxwell relationsLorentz forceAction (physics)
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The time-harmonic Maxwell equations

1996

In this chapter we shall see that the solution of the time-harmonic Maxwell equations with real coefficients can be transformed to time independent partial differential equations with complex coefficients. Then we introduce a finite element approximation proposed in [Křižek, Neittaanmaki, 1989]. A similar technique is analyzed in [Křižek, Neittaanmaki, 1984b], [Monk, 1992a] (for fully time dependent problems see, e.g., [Monk 1992b,c]).

Physicssymbols.namesakeJefimenko's equationsClassical mechanicsTheoretical and experimental justification for the Schrödinger equationMaxwell's equationsMaxwell's equations in curved spacetimesymbolsInhomogeneous electromagnetic wave equationMatrix representation of Maxwell's equationsMaxwell relationsElectromagnetic tensor
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