English

Sharp complexity phase transitions generated by entanglement

Quantum Physics 2023-08-02 v1 Computational Complexity

Abstract

Entanglement is one of the physical properties of quantum systems responsible for the computational hardness of simulating quantum systems. But while the runtime of specific algorithms, notably tensor network algorithms, explicitly depends on the amount of entanglement in the system, it is unknown whether this connection runs deeper and entanglement can also cause inherent, algorithm-independent complexity. In this work, we quantitatively connect the entanglement present in certain quantum systems to the computational complexity of simulating those systems. Moreover, we completely characterize the entanglement and complexity as a function of a system parameter. Specifically, we consider the task of simulating single-qubit measurements of kk--regular graph states on nn qubits. We show that, as the regularity parameter is increased from 11 to n1n-1, there is a sharp transition from an easy regime with low entanglement to a hard regime with high entanglement at k=3k=3, and a transition back to easy and low entanglement at k=n3k=n-3. As a key technical result, we prove a duality for the simulation complexity of regular graph states between low and high regularity.

Keywords

Cite

@article{arxiv.2212.10582,
  title  = {Sharp complexity phase transitions generated by entanglement},
  author = {Soumik Ghosh and Abhinav Deshpande and Dominik Hangleiter and Alexey V. Gorshkov and Bill Fefferman},
  journal= {arXiv preprint arXiv:2212.10582},
  year   = {2023}
}
R2 v1 2026-06-28T07:45:32.387Z