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Thermal hysteresis and its impact on the efficiency of first-order caloric materials

T. Hess, Lena Maria Maier, Nora Bachmann, Patrick Corhan, Olaf Schäfer-Welsen, Jürgen Wöllenstein, Kilian Bartholomé

2020Journal of Applied Physics55 citationsDOIOpen Access PDF

Abstract

Cooling with caloric materials could be an option to replace compressor-based cooling systems in the future. In addition to the advantage of avoiding dangerous liquid coolants, one often cites a possible higher efficiency of the calorific cooling systems compared to compressor-based systems. But is that true? The aim of this work is to assess the efficiency potential of caloric cooling systems on a very basic material level. We placed our focus on materials with a first-order phase change since they generally show a large caloric response. We derive a relation between thermal hysteresis and the dissipative losses due to hysteresis. To predict the efficiency, this relation is integrated in a Carnot-like cycle. This approach was chosen to get access to the efficiency reduction due to hysteresis without any further losses due to other nonidealities of the thermodynamic cycle. As a main finding, we present a direct relation between thermal hysteresis and the expected maximum exergy or second-law efficiency of a caloric cooling device. These results indicate that, for many caloric materials, the thermal hysteresis needs to be further reduced to be able to compete with the efficiency of compressor-based systems.

Topics & Concepts

Carnot cycleCaloric theoryHysteresisGas compressorThermal efficiencyThermodynamicsWork outputCooling capacityExergyMaterials scienceControl theory (sociology)MechanicsComputer sciencePhysicsCombustionChemistryControl (management)Organic chemistryArtificial intelligenceQuantum mechanicsAdvanced Thermodynamics and Statistical MechanicsAdvanced Thermoelectric Materials and DevicesThermal properties of materials
Thermal hysteresis and its impact on the efficiency of first-order caloric materials | Litcius