Logarithmic light cone, slow entanglement growth and scrambling, and quantum memory

Effective light cones may emerge in non-relativistic local quantum systems from the Lieb-Robinson bounds, resulting in exponentially decaying commutator norms of two space-time separated operators in the Heisenberg picture. Here, we derive a mechanism for the emergence and consequences of a logarithmic light cone (LLC). As a possible way, the LLC can emerge from a phenomenological model of many-body-localization. We show that the information scrambling is logarithmically slow in the regime of the LLC. We prove that the bipartite entanglement entropy grows logarithmically with time at arbitrary finite space dimensions and for arbitrary initial pure states. As an application in quantum information processing, the LLC supports long-lived quantum memory, a quantum code with macroscopic code distance and an exponentially long lifetime after unitary time evolution.
Comment: 6+3 pages, 2 figures