Spectral Certificates and Sum-of-Squares Lower Bounds for Semirandom Hamiltonians
Abstract
The k-XOR problem is one of the most well-studied problems in classical complexity. We study a natural quantum analogue of k-XOR, the problem of computing the ground energy of a certain subclass of structured local Hamiltonians, signed sums of k-local Pauli operators, which we refer to as k-XOR Hamiltonians. As an exhibition of the connection between this model and classical k-XOR, we extend results on refuting k-XOR instances to the Hamiltonian setting by crafting a quantum variant of the Kikuchi matrix for CSP refutation, instead capturing ground energy optimization. As our main result, we show an nO()-time classical spectral algorithm certifying ground energy at most 12 + in (1) semirandom Hamiltonian k-XOR instances or (2) sums of Gaussian-signed k-local Paulis both with O(n) · (n)k/2-1 n /4 local terms, a tradeoff known as the refutation threshold. Additionally, we give evidence this tradeoff is tight in the semirandom regime via non-commutative Sum-of-Squares lower bounds embedding classical k-XOR instances as entirely classical Hamiltonians.
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