The Complexity of Translationally Invariant Problems beyond Ground State Energies

TL;DR

This paper proves that certain quantum complexity problems remain hard even in translationally invariant systems, by developing generic methods to lift known hardness results to these simpler, symmetric systems.

Contribution

It introduces a framework for transferring hardness results to translationally invariant Hamiltonians, demonstrating intractability of APX-SIM and GSCON in such systems.

Findings

APX-SIM remains $ ext{P}^{ ext{QMA}_{ ext{EXP}}}$-complete in translationally invariant systems.

GSCON remains $ ext{QCMA}_{ ext{EXP}}$-complete even with highly non-local adversaries.

Develops a generic lifting theorem for hardness results in quantum Hamiltonian problems.

Abstract

It is known that three fundamental questions regarding local Hamiltonians -- approximating the ground state energy (the Local Hamiltonian problem), simulating local measurements on the ground space (APX-SIM), and deciding if the low energy space has an energy barrier (GSCON) -- are $\mathsf{QMA}$-hard, $\mathsf{P}^{\mathsf{QMA}[log]}$-hard and $\mathsf{QCMA}$-hard, respectively, meaning they are likely intractable even on a quantum computer. Yet while hardness for the Local Hamiltonian problem is known to hold even for translationally-invariant systems, it is not yet known whether APX-SIM and GSCON remain hard in such "simple" systems. In this work, we show that the translationally invariant versions of both APX-SIM and GSCON remain intractable, namely are $\mathsf{P}^{\mathsf{QMA}_{\mathsf{EXP}}}$- and $\mathsf{QCMA}_{\mathsf{EXP}}$-complete, respectively. Each of these results is attained by giving a respective generic "lifting theorem" for producing hardness results. For APX-SIM, for example, we give a framework for "lifting" any abstract local circuit-to-Hamiltonian mapping $H$ (satisfying mild assumptions) to hardness of APX-SIM on the family of Hamiltonians produced by $H$, while preserving the structural and geometric properties of $H$ (e.g. translation invariance, geometry, locality, etc). Each result also leverages counterintuitive properties of our constructions: for APX-SIM, we "compress" the answers to polynomially many parallel queries to a QMA oracle into a single qubit. For GSCON, we give a hardness construction robust against highly non-local unitaries, i.e. even if the adversary acts on all but one qudit in the system in each step.