Spread complexity and topological transitions in the Kitaev chain

A number of recent works have argued that quantum complexity, a well-known concept in computer science that has re-emerged recently in the context of the physics of black holes, may be used as an efficient probe of novel phenomena such as quantum chaos and even quantum phase transitions. In this article, we provide further support for the latter, using a 1-dimensional p-wave superconductor - the Kitaev chain - as a prototype of a system displaying a topological phase transition. The Hamiltonian of the Kitaev chain manifests two gapped phases of matter with fermion parity symmetry; a trivial strongly-coupled phase and a topologically non-trivial, weakly-coupled phase with Majorana zero-modes. We show that Krylov-complexity (or, more precisely, the associated spread-complexity) is able to distinguish between the two and provides a diagnostic of the quantum critical point that separates them. We also comment on some possible ambiguity in the existing literature on the sensitivity of different measures of complexity to topological phase transitions.

Automated summary

Recent research has shown the potential of quantum complexity to probe phenomena such as quantum chaos and quantum phase transitions. This article provides further evidence by studying the Kitaev chain as a model system for topological phase transitions. The authors demonstrate that Krylov-complexity can distinguish between different phases and serve as a diagnostic tool for the quantum critical point.