Boundary layers and universal distribution in boundary driven active systems

We study non-interacting run-and-tumble particles (RTPs) in one dimension driven by particle reservoirs at the boundaries. Analytical results for the steady state and dynamics are obtained and new active features are observed. In steady state, a Seebeck-like effect is identified. The spatial and internal degrees of freedom, combined together, possess a symmetry, using which we found the eigenspectrum for large systems. The eigenvalues are arranged in two distinct bands. There is a crossover from system size-independent relaxation rate to the diffusive relaxation as the system size is increased. The time-dependent distribution is calculated and extended to the semi-infinite line. In the dynamics, a 'Milne length' emerges that depends non-trivially on diffusivity and other parameters. Notably, the large time distribution retains a strong and often dominant 'active' contribution in the bulk, implying that an effective passive-like description is inadequate. We report the existence of a 'kinetic boundary layer' both in the steady-state and time-dependent regime, which is a consequence of thermal diffusion. In the absorbing boundary problem, a novel universality is proposed when the particle is driven by short-ranged colored noise.