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The coupling of active, self-motile particles to topological constraints can
give rise to novel non-equilibrium dynamical patterns that lack any passive
counterpart. Here we study the behavior of self-propelled rods confined to a compact
spherical manifold by means of Brownian dynamics simulations. We establish the
state diagram and find that short active rods at sufficiently high density exhibit a
glass transition toward a disordered state characterized by persistent
self-spinning motion. By periodically melting and revitrifying the spherical
spinning glass, we observe clear signatures of time-dependent aging and
rejuvenation physics. We quantify the crucial role of activity in these
non-equilibrium processes, and rationalize the aging dynamics in terms of an
absorbing-state transition toward a more stable active glassy state. Our results
demonstrate both how concepts of passive glass phenomenology can carry over into
the realm of active matter, and how topology can enrich the collective
spatiotemporal dynamics in inherently non-equilibrium systems.
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