Higher-Order Token Interactions via Quantum Attention

Abstract

Standard dot-product self-attention computes, in a single layer, only pairwise (order-2) interactions between tokens; representing a generic order-k interaction is known to require either super-quadratic resources in one layer or composition across depth. We introduce Quantum Higher-Order Attention (QHA), a shallow, hardware-realizable quantum attention head that, via data re-uploading and an all-to-all non-Clifford entangler, synthesizes order-k token interactions inside the circuit and exposes them through a local single-qubit read-out. We prove (i) an expressivity separation: any single standard self-attention layer with embedding dimension m, H heads and p-bit precision satisfying mHp=o(N/ N) cannot represent the order-k correlation family that one QHA head represents with circuit depth O( k) (O(k) two-qubit gates); and (ii) a trainability guarantee for its local-design instantiation: with a local read-out and O( n) depth the gradient variance is Ω(1/poly(n)) (no barren plateau), which we confirm empirically -- while being explicit that the more expressive all-to-all instantiation we benchmark is trained empirically and shows exponentially decaying gradients. Empirically, at a 6.5× smaller parameter budget, QHA generalizes hidden-subset parity of every order k6 from disjoint inputs, whereas the larger classical attention head collapses past order~2; consistent with theory, the size of the advantage tracks the target's Fourier degree - largest for parity and shrinking when low-order structure is present. As an application, QHA serves as a compact high-order interaction detector across three domains - genetic epistasis, learning-parity-with-noise, and graph triangle detection - reaching the noise ceiling at the smallest parameter budget where field-standard linear methods fail.