Litcius/Paper detail

A Thermodynamic Approach to Measuring Entropy in a Few-Electron Nanodevice

Eugenia Pyurbeeva, Jan A. Mol

2021Entropy20 citationsDOIOpen Access PDF

Abstract

The entropy of a system gives a powerful insight into its microscopic degrees of freedom; however, standard experimental ways of measuring entropy through heat capacity are hard to apply to nanoscale systems, as they require the measurement of increasingly small amounts of heat. Two alternative entropy measurement methods have been recently proposed for nanodevices: through charge balance measurements and transport properties. We describe a self-consistent thermodynamic framework for applying thermodynamic relations to few-electron nanodevices-small systems, where fluctuations in particle number are significant, whilst highlighting several ongoing misconceptions. We derive a relation (a consequence of a Maxwell relation for small systems), which describes both existing entropy measurement methods as special cases, while also allowing the experimentalist to probe the intermediate regime between them. Finally, we independently prove the applicability of our framework in systems with complex microscopic dynamics-those with many excited states of various degeneracies-from microscopic considerations.

Topics & Concepts

Statistical physicsEntropy (arrow of time)PhysicsFundamental thermodynamic relationDetailed balanceExcited stateMaximum entropy thermodynamicsEntropy productionNanodeviceThermodynamic systemMaxwell relationsThermodynamic processHeat capacityMeasurement uncertaintySpecific heatPrinciple of maximum entropyMaterial propertiesThermodynamicsTheoretical physicsNon-equilibrium thermodynamicsAdvanced Thermodynamics and Statistical MechanicsMolecular Junctions and NanostructuresQuantum and electron transport phenomena
A Thermodynamic Approach to Measuring Entropy in a Few-Electron Nanodevice | Litcius