Enhanced Dissipation via Time-Dependent Velocity Fields: Acceleration and Intermittency (2501.16905v1)

Abstract: Motivated by mixing processes in analytical laboratories, this work investigates enhanced dissipation in non-autonomous flows. Specifically, we study the evolution of concentrations governed by the advection-diffusion equation, where the velocity field is modelled as the product of a shear flow (with simple critical points) and a time-dependent function $\xi(t)$. The main objective of this paper is to derive explicit, quantitative estimates for the energy decay rates, which are shown to depend sensitively on the properties of $\xi$. We identify a class of time-dependent functions $\xi$ that are bounded above and below by increasing functions of time. For this class, we demonstrate super-enhanced dissipation, characterized by energy decay rates faster than those observed in autonomous cases (e.g., when $\xi \equiv 1$, as in Coti Zelati and Gallay (2023)). Additionally, we explore enhanced dissipation in the context of intermittent flows, where the velocity fields may be switched on and off over time. In these cases, the dissipation rates are comparable to those of autonomous flows but with modified constants. To illustrate our results, we analyse two prototypical intermittent flows: one that exhibits a gradual turn-on and turn-off phase, and another that undergoes a significant acceleration following a slow initial activation phase. For the second, we derive the corresponding dissipation rate using a gluing argument. Both results are achieved through the application of the hypocoercivity framework (`a la Bedrossian and Coti Zelati (2017)), adapted to an augmented functional with time-dependent weights. These weights are designed to dynamically counteract the potential growth of $\xi$, ensuring robust estimates for the energy decay.