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Perturbative gadgets without strong interactions

Quantum Physics 2015-11-24 v1

Abstract

Perturbative gadgets are used to construct a quantum Hamiltonian whose low-energy subspace approximates a given quantum kk-body Hamiltonian up to an absolute error ϵ\epsilon. Typically, gadget constructions involve terms with large interaction strengths of order poly(ϵ1)\text{poly}(\epsilon^{-1}). Here we present a 2-body gadget construction and prove that it approximates a target many-body Hamiltonian of interaction strength γ=O(1)\gamma = O(1) up to absolute error ϵγ\epsilon\ll\gamma using interactions of strength O(ϵ)O(\epsilon) instead of the usual inverse polynomial in ϵ\epsilon. A key component in our proof is a new condition for the convergence of the perturbation series, allowing our gadget construction to be applied in parallel on multiple many-body terms. We also show how to apply this gadget construction for approximating 3- and kk-body Hamiltonians. The price we pay for using much weaker interactions is a large overhead in the number of ancillary qubits, and the number of interaction terms per particle, both of which scale as O(poly(ϵ1))O(\text{poly}(\epsilon^{-1})). Our strong-from-weak gadgets have their primary application in complexity theory (QMA hardness of restricted Hamiltonians, a generalized area law counterexample, gap amplification), but could also motivate practical implementations with many weak interactions simulating a much stronger quantum many-body interaction.

Cite

@article{arxiv.1408.5881,
  title  = {Perturbative gadgets without strong interactions},
  author = {Yudong Cao and Daniel Nagaj},
  journal= {arXiv preprint arXiv:1408.5881},
  year   = {2015}
}

Comments

26 pages, 8 figures

R2 v1 2026-06-22T05:39:10.951Z