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History-state Hamiltonians are critical

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arxiv 1810.06528 v1 pith:XCMHRNYL submitted 2018-10-15 quant-ph

History-state Hamiltonians are critical

classification quant-ph
keywords hamiltonianshistorystatecomputationquantumcircuitscriticalgapped
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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All Hamiltonian complexity results to date have been proven by constructing a local Hamiltonian whose ground state -- or at least some low-energy state -- is a "computational history state", encoding a quantum computation as a superposition over the history of the computation. We prove that all history-state Hamiltonians must be critical. More precisely, for any circuit-to-Hamiltonian mapping that maps quantum circuits to local Hamiltonians with low-energy history states, there is an increasing sequence of circuits that maps to a growing sequence of Hamiltonians with spectral gap closing at least as fast as O(1/n) with the number of qudits n in the circuit. This result holds for very general notions of history state, and also extends to quasi-local Hamiltonians with exponentially-decaying interactions. This suggests that QMA-hardness for gapped Hamiltonians (and also BQP-completeness of adiabatic quantum computation with constant gap) either require techniques beyond history state constructions. Or gapped Hamiltonians cannot be QMA-hard (respectively, BQP-complete).

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Cited by 1 Pith paper

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Analogue quantum simulation with polylogarithmic interaction strengths by extrapolating within phases of matter

    quant-ph 2026-05 unverdicted novelty 7.0

    For non-critical systems, analogue quantum simulation via perturbative gadgets requires only polylogarithmic interaction strengths through extrapolation within phases of matter.