Emergence of Entropic Time in a Tabletop Wheeler-DeWitt Universe
Abstract
We implement an analogue Wheeler-DeWitt mini-universe constituted by a well-isolated atomic Bose-Einstein condensate in a time-independent conservative potential. In exact analogy with the Wheeler-DeWitt framework for the actual universe, our system has the fundamental problem of defining from within a meaningful time variable over which to order the events. Here, we partition the mini-universe into a bright and a dark sector, enabling entropy exchange between them through a potential barrier. We show that the Hamiltonian of the condensate in the bright sector is analogous to the one in canonical minisuperspace models. We define an entropic time and show with experimental data that it is robustly monotonic even when the bright sector undergoes several cycles that begin with a 'big bang' and end with a 'big crunch'. By tuning the barrier height, we control the rate of entropy production and thus the speed of the emergent entropic time and the dynamics of the bright universe. We finally derive an entropic time-dependent Schroedinger equation that could be considered as a generalization of the standard one, and use it to reproduce our data. This work experimentally validates the proposition that time in quantum cosmological models may not be fundamental, but instead emerges from thermodynamic gradients, while establishing a concrete experimental platform for evaluating several aspects of quantum gravity theories.