In mesoscopic and nanoscale systems at low temperatures, charge carriers are
typically not in thermal equilibrium with the surrounding lattice. The
resulting, non-equilibrium dynamics of electrons has only begun to be explored.
Experimentally the time-dependence of the electron temperature (deviating from
the lattice temperature) has been investigated in small metallic islands.
Motivated by these experiments we investigate theoretically the electronic
energy and temperature fluctuations in a metallic island in the Coulomb
blockade regime, tunnel coupled to an electronic reservoir, i.e. a single
electron box. We show that electronic quantum tunnelling between the island and
the reservoir, in the absence of any net charge or energy transport, induces
fluctuations of the island electron temperature. The full distribution of the
energy transfer as well as the island temperature is derived within the
framework of full counting statistics. In particular, the low-frequency
temperature fluctuations are analysed, fully accounting for charging effects
and non-zero reservoir temperature. The experimental requirements for measuring
the predicted temperature fluctuations are discussed.Comment: 20 pages, 4 figures, submitted to NJP special issue on Quantum
Thermodynamic