Chaotic unitary time evolution in closed quantum systems spreads initially localized quantum information to non-local degrees of freedom. This delocalization by the intrinsic dynamics has the potential to hide information against the destructive effect of a dissipative environment giving rise to local noise. Investigating the robustness of quantum information under this complicated interplay of unitary spreading and dissipation offers a new perspective on exploring dissipative dynamical phases, while the emerging dynamical regimes have potential applications in designing quantum codes. In this work, we demonstrate a rich dynamical phase diagram in a one-dimensional quantum many-body system subject to dissipation at the boundary, displaying different regimes distinguished by the fate of quantum information at late times. Specifically, we find coding transitions between a phase where the information remains protected even at time scales where thermalization is typically expected, and a regime with all information leaked to the environment. In particular, intrinsic dynamics alone can protect a finite density of information, allowing the stable encoding of information at finite rate. 

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