Thermodynamic properties of the one-dimensional Robin quantum well

Abstract

Thermodynamic properties of Robin quantum well with extrapolation length are analyzed theoretically both for canonical and two grand canonical ensembles with special attention being paid to situation when energies of one or two lowest-lying states are split-off from rest of spectrum by large gap that is controlled by varying . For single split-off level, which exists for the geometry with equal magnitudes but opposite signs of Robin distances on confining interfaces, heat capacity cV of canonical averaging is a nonmonotonic function of temperature T with its salient maximum growing to infinity as 2 for decreasing to zero extrapolation length and its position being proportional to 1/(2). Specific heat per particle cN of Fermi-Dirac ensemble depends nonmonotonically on temperature too with its pronounced extremum being foregone on T axis by plateau whose value at dying is (N-1)/(2N)kB, with N being a number of fermions. Maximum of cN, similar to canonical averaging, unrestrictedly increases as goes to zero and is the largest for one particle. Most essential property of Bose-Einstein ensemble is a formation, for growing number of bosons, of sharp asymmetric shape on the cN-T characteristics that is more protrusive at the smaller Robin distances. This cusp-like structure is a manifestation of the phase transition to the condensate state. For two split-off orbitals, one additional maximum emerges whose position is shifted to colder temperatures with increase of energy gap between these two states and their higher-lying counterparts and whose magnitude approaches -independent value. All these physical phenomena are qualitatively and quantitatively explained by variation of energy spectrum by Robin distance.