Exclusion Statistics as a Thermodynamic Resource in Quantum Heat Engines

Abstract

The maximum power extractable from a quantum thermoelectric heat engine operating with free fermion carriers is bounded by the universal Whitney limit, Pfermion 0.0321π2 kB2(TL-TR)2/h. We demonstrate that this bound is not fundamental to quantum heat engines but is instead an artifact of fermionic statistics. Within the nonlinear Landauer-Büttiker framework, a bosonic working medium yields a strictly enhanced universal maximum power, Pboson = ( 2)2\, kB2(TL-TR)2/h, exceeding the fermionic limit by a factor of ( 2)2/(0.0321π2) ≈ 1.52. We propose magnon transport through a ferromagnetic spin chain as an experimentally viable bosonic realization. Incorporating Haldane fractional exclusion statistics with parameter g provides a continuous interpolation between the bosonic (g = 0) and fermionic (g = 1) limits, revealing a monotonic enhancement of maximum power for g < 1 at reduced bias cost. These results establish quantum statistical exclusion as a previously unrecognized and independently tunable thermodynamic resource, opening performance regimes inaccessible to conventional carrier-engineering approaches.