Discrete Quantum Gaussians and Central Limit Theorem (2302.08423v2)

Abstract: We introduce a quantum convolution and a conceptual framework to study states in discrete-variable (DV) quantum systems. All our results suggest that stabilizer states play a role in DV quantum systems similar to the role Gaussian states play in continuous-variable systems; hence we suggest the name ''discrete quantum Gaussians'' for stabilizer states. For example, we prove that the convolution of two stabilizer states is another stabilizer state, and that stabilizer states extremize both quantum entropy and Fisher information. We establish a ''maximal entropy principle,'' a ''second law of thermodynamics for quantum convolution,'' and a quantum central limit theorem (QCLT). The latter is based on iterating the convolution of a zero-mean quantum state, which we prove converges to a stabilizer state. We bound the exponential rate of convergence of the QCLT by the ''magic gap,'' defined by the support of the characteristic function of the state. We elaborate our general results with a discussion of some examples, as well as extending many of them to quantum channels.