Quantum 2-SAT on low dimensional systems is QMA1-complete: Direct embeddings and black-box simulation

Abstract

Despite the fundamental role the Quantum Satisfiability (QSAT) problem has played in quantum complexity theory, a central question remains open: At which local dimension does the complexity of QSAT transition from "easy" to "hard"? Here, we study QSAT with each constraint acting on a k-dimensional and l-dimensional qudit pair, denoted (k,l)-QSAT. Our first main result shows that, surprisingly, QSAT on qubits can remain QMA1-hard, in that (2,5)-QSAT is QMA1-complete. In contrast, 2-SAT on qubits is well-known to be poly-time solvable [Bravyi, 2006]. Our second main result proves that (3,d)-QSAT on the 1D line with d∈ O(1) is also QMA1-hard. Finally, we initiate the study of 1D (2,d)-QSAT by giving a frustration-free 1D Hamiltonian with a unique, entangled ground state. Our first result uses a direct embedding, combining a novel clock construction with the 2D circuit-to-Hamiltonian construction of [Gosset, Nagaj, 2013]. Of note is a new simplified and analytic proof for the latter (as opposed to a partially numeric proof in [GN13]). This exploits Unitary Labelled Graphs [Bausch, Cubitt, Ozols, 2017] together with a new "Nullspace Connection Lemma", allowing us to break low energy analyses into small patches of projectors, and to improve the soundness analysis of [GN13] from (1/T6) to (1/T2), for T the number of gates. Our second result goes via black-box reduction: Given an arbitrary 1D Hamiltonian H on d'-dimensional qudits, we show how to embed it into an effective null-space of a 1D (3,d)-QSAT instance, for d∈ O(1). Our approach may be viewed as a weaker notion of "simulation" (\`a la [Bravyi, Hastings 2017], [Cubitt, Montanaro, Piddock 2018]). As far as we are aware, this gives the first "black-box simulation"-based QMA1-hardness result, i.e. for frustration-free Hamiltonians.