Universal trade-off structure between symmetry, irreversibility, and quantum coherence in quantum processes

Abstract

Symmetry, irreversibility, and quantum coherence are foundational concepts in physics. Here, we present a universal tradeoff relation between these three concepts. This particularly reveals that (1) under a global symmetry, any attempt to change the local conserved charge causes inevitable irreversibility, and (2) such irreversibility can be mitigated by quantum coherence. Our tradeoff relation follows solely from the unitarity and global symmetry of the total dynamics, allowing for general applicability. For non-equilibrium physics, it relates the coherence cost and the entropy production -- representing thermodynamic irreversibility -- in arbitrary quantum processes. It also provides fundamental limitations on the capability of a number of quantum information processing tasks -- such as gate and measurement implementation and error correction -- that involve symmetry restrictions. Furthermore, it predicts how many bits of classical information thrown into a black hole become unreadable under energy conservation. Our tradeoff relation is based on quantum uncertainty relation, showcasing intimate connections between fundamental physical principles and ultimate operational capability of quantum processes.