Extreme-temperature single-particle heat engine

Carnot famously showed that engine operation is chiefly characterised by the magnitude of the temperature ratio $T_\mathrm{h}/T_\mathrm{c}$ between its hot and cold reservoirs. While temperature ratios ranging between $1.3-2.8$ and $2-10$ are common in macroscopic commercial engines and engines operating in the microscopic regime, respectively, the quest is to test thermodynamics at its extremes. Here we present the hottest engine on earth, with temperature ratios as high as $110$. We achieve this by realising an underdamped single-particle engine using a charged microparticle that is electrically levitated under vacuum conditions. Noisy electric fields are used to synthesise reservoir temperatures in excess of $10^7$ K. As a result, giant fluctuations show up in all thermodynamic quantities of the engine, such as heat exchange and efficiency. Moreover, we find that the particle experiences an effective position dependent temperature, which gives rise to dynamics that drastically deviates from that of standard Brownian motion. We develop a theoretical model accounting for the effects of this multiplicative noise and find excellent agreement with the measured dynamics. The high level of control over the presented experimental platform opens the door to emulate the stochastic dynamics of cellular and biological processes, and provides thermodynamic insight required for the development of nanotechnologies.