The Complexity of Translationally Invariant Spin Chains with Low Local Dimension

Bausch, Johannes; Cubitt, Toby S.; Ozols, Māris

doi:10.1007/s00023-017-0609-7

Cited by 32 publications

(64 citation statements)

References 42 publications

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“…An important open question is whether it is possible to reduce the local state dimension in these translationally invariant constructions, while preserving universality. One possible approach would be to apply the techniques from [BCO17], which were used to reduce the local dimension of qudits used in translationally invariant QMA-complete local Hamiltonian constructions.…”

Section: Discussionmentioning

confidence: 99%

Translationally Invariant Universal Classical Hamiltonians

Kohler

Cubitt

2019

J Stat Phys

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Recent work has characterised rigorously what it means for one quantum system to simulate another, and demonstrated the existence of universal Hamiltonians-simple spin lattice Hamiltonians that can replicate the entire physics of any other quantum many body system. Previous universality results have required proofs involving complicated 'chains' of perturbative 'gadgets'. In this paper, we derive a significantly simpler and more powerful method of proving universality of Hamiltonians, directly leveraging the ability to encode quantum computation into ground states. This provides new insight into the origins of universal models, and suggests a deep connection between universality and complexity. We apply this new approach to show that there are universal models even in translationally invariant spin chains in 1D. This gives as a corollary a new Hamiltonian complexity result, that the local Hamiltonian problem for translationally-invariant spin chains in one dimension with an exponentially-small promise gap is PSPACE-complete. Finally, we use these new universal models to construct the first known toy model of 2D-1D holographic duality between local Hamiltonians.

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Section: Discussionmentioning

confidence: 99%

Translationally Invariant Universal Classical Hamiltonians

Kohler

Cubitt

2019

J Stat Phys

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“…The construction we propose in this paper with at most 4-local interactions between spins of dimension 4 yields 4 8 degrees of freedom, a roughly two orders-of-magnitude improvement over a straightforward embedding of the best one-dimensional construction, and en par with the best non-translationally-invariant result. It also shows that there is only about three orders of magnitude left between this construction and spin systems that we encounter every day (e.g.…”

Section: In This Paper We Prove That the Local Hamiltonian Problem Rmentioning

confidence: 95%

“…Enforcing translational invariance, we can regard e.g. [8]-nearest-neighbour interactions between spins of dimension ≈ 50-which would give roughly (50 2 ) 2 ≈ 6 × 10 6 parameters to choose from.…”

Section: In This Paper We Prove That the Local Hamiltonian Problem Rmentioning

confidence: 99%

“…QMA EXP is similar to QMA, the quantum analogue of NP, but with an exponential-time verifier instead of polynomialtime-a necessary technicality for any translationally invariant result [8,13], since an n-qudit instance can only encode poly(log n) bits of information (in this case the side lengths of the lattice, which encode the input in unary). In essence, while a QMA EXP -hard problem can be verified in exponential time on a quantum computer, just as in the P vs. NP case it is not expected to be solved as efficiently (see appendix A for details).…”

Section: Theorem 1 the Local Hamiltonian Problem Is Qma Expcompletementioning

confidence: 99%

“…Kitaev's seminal paper proving quantum-NP-hardness of the local Hamiltonian problem for the case that each interaction couples at most five spins [1] motivated significant progress towards understanding the computational complexity that arises in different variants of the local Hamiltonian problem [2][3][4][5][6][7][8][9][10]. These results are especially interesting from a computational perspective, answering which families of Hamiltonians are "complicated enough" to perform universal quantum computation [11,12].…”

Section: Introductionmentioning

confidence: 99%

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The complexity of translationally invariant low-dimensional spin lattices in 3D

Bausch

Piddock

2017

Journal of Mathematical Physics

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In this paper, we consider spin systems in three spatial dimensions, and prove that the local Hamiltonian problem for 3D lattices with face-centered cubic unit cells, 4-local translationally-invariant interactions between spin-3/2 particles and open boundary conditions is QMA EXP -complete. We go beyond a mere embedding of past hard 1D history state constructions, and utilize a classical Wang tiling problem as binary counter in order to translate one cube side length into a binary description for the verifier input. We further make use of a recently-developed computational model especially well-suited for history state constructions, and combine it with a specific circuit encoding shown to be universal for quantum computation. These novel techniques allow us to significantly lower the local spin dimension, surpassing the best translationally-invariant result to date by two orders of magnitude (in the number of degrees of freedom per coupling). This brings our models en par with the best non-translationally-invariant construction.arXiv:1702.08830v1 [quant-ph]

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Perturbation Gadgets: Arbitrary Energy Scales from a Single Strong Interaction

Bausch

2019

Ann. Henri Poincaré

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Fundamentally, it is believed that interactions between physical objects are two-body.Perturbative gadgets are one way to break up an effective many-body coupling into pairwise interactions: a Hamiltonian with high interaction strength introduces a low-energy space in which the effective theory appears k-body and approximates a target Hamiltonian to within precision . One caveat of existing constructions is that the interaction strength generally scales exponentially in the locality of the terms to be approximated, i.e. as Ω(1/ k ); if = 1/poly n in the system size n, as is necessary for e.g. QMA-hardness constructions, the energy differences become highly unphysical.In this work we propose a many-body Hamiltonian construction which introduces only a single separate energy scale of order Θ(1/N 2+δ ), for a small parameter δ > 0, and for N terms in the target Hamiltonian-i.e. all local terms of the simulator have either this norm, or one of O(1). In its low-energy subspace, we can approximate any normalized target Hamiltonian H t = N i=1 h i with norm ratios r = h i 2 / h j 2 = O(exp(exp(poly n))) to within relative precision O(N −δ ). This comes at the expense of increasing the locality by at most one, and adding an at most poly-sized ancilliary system for each coupling; the ancillas being qutrits for exponential scaling, and qudits for doubly exponential r; the interactions on the ancilliary system are geometrically local, and can be translationally-invariant.In order to prove this claim, we borrow a technique from high energy physics-where matter fields obtain effective properties (such as mass) from interactions with an exchange particle-and a tiling Hamiltonian to drop all cross terms at higher expansion orders, which simplifies the analysis of a traditional Feynman-Dyson series expansion.As an application, we discuss implications for QMA-hardness of the L H problem, and argue that "almost" translational invariance-defined as arbitrarily small relative variations of the strength of the local terms-is as good as non-translational-invariance in many of the constructions used throughout Hamiltonian complexity theory. We furthermore show that the choice of geared limit of many-body systems, where e.g. width and height of a lattice are taken to infinity in a specific relation, can have different complexity-theoretic implications: even for translationally-invariant models, changing the geared limit can vary the hardness of finding the ground state energy with respect to a given promise gap from computationally trivial, to QMA EXP -, or even BQEXPSPACE-complete.

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The Complexity of Translationally Invariant Spin Chains with Low Local Dimension

Cited by 32 publications

References 42 publications

Translationally Invariant Universal Classical Hamiltonians

Translationally Invariant Universal Classical Hamiltonians

The complexity of translationally invariant low-dimensional spin lattices in 3D

Perturbation Gadgets: Arbitrary Energy Scales from a Single Strong Interaction

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