Under certain conditions, it takes a shorter time to cool a hot system than to cool the same system initiated at a lower temperature. This phenomenon, the "Mpemba Effect," was first observed in water and has recently been reported in other systems. Whereas several detail-dependent explanations were suggested for some of these observations, no common underlying mechanism is known.
Using the theoretical framework of nonequilibrium thermodynamics, Assistant Professor Zhiyue Lu, published in PNAS, present a widely applicable mechanism for a similar effect, the Markovian Mpemba effect, derive a sufficient condition for its appearance, and demonstrate it explicitly in three paradigmatic systems: the Ising model, diffusion dynamics, and a three-state system. In addition, he predicts predict an inverse Markovian Mpemba effect in heating. Under proper conditions, a cold system can heat up faster than the same system initiated at a higher temperature.
Professor Lu numerically demonstrates that this inverse effect is expected in a 1D antiferromagnet nearest-neighbors interacting Ising chain in the presence of an external magnetic field. His results shed light on the mechanism behind anomalous heating and cooling and suggest that it should be possible to observe these in a variety of systems.