Which Coherence Decoheres? Basis-Dependent Decoherence Rates in Symmetry-Broken Collective Spin Systems

Abstract

In the ordered phase of a Z2-symmetric collective spin system, two natural bases -- localised pointer states \|P,|R\ and energy eigenstates \|E0,|E1\ -- yield Lindblad dephasing rates that differ by a factor approaching 2 as N∞ and reaching 2.42 near the quantum-critical crossover. The discrepancy has a single algebraic origin: parity forces Ei|Jz|Ei=0 exactly, eliminating the cross-term that doubles the localised-state rate. Two distinct protection factors are identified: η MF=(Nm*)2/(2G01)≈2.42, where m* is the order parameter and G01=12( E0|Jz2|E0+ E1|Jz2|E1) (advantage over the classical mean-field estimate), and η exact=(G01+J012)/G01≈1.86, where J01= E0|Jz|E1 (exact physical ratio of pointer-state to eigenstate decay rate). In the thermodynamic limit the secular approximation fails, the doublet degenerates, and both rates converge. The three-regime structure is demonstrated in the Lipkin-Meshkov-Glick model via exact diagonalisation, and the algebraic origin of the discrepancy is established via the Z2 parity of the Lindblad jump operator.