Graph-State Circuit Blocks control Entanglement and Scrambling Velocities

TL;DR

This paper demonstrates that the internal structure of graph-state circuit blocks significantly affects entanglement and scrambling velocities in quantum circuits, revealing a hierarchy of dynamical rates influenced by graph properties.

Contribution

It introduces a family of exactly simulable Clifford circuits with graph-state blocks, showing how their internal structure impacts entanglement and operator spreading rates.

Findings

Different graph-state blocks lead to varying entanglement velocities.

Inequivalent graph states under local Clifford transformations produce different dynamical rates.

Entanglement distribution and graph connectivity profiles correlate with growth and spreading velocities.

Abstract

Random circuit models often describe local dynamics using generic two-qubit gates, which have proven successful in capturing entanglement growth and operator spreading in many contexts. This approach naturally leads to the expectation that detailed gate structure plays only a limited role in coarse-grained entanglement and scrambling diagnostics. We show that the internal structure of multipartite circuit primitives can significantly influence these dynamical rates, even within a fixed random-circuit architecture. To investigate this, we study an exactly simulable family of Clifford quantum circuits built from fixed $n$-qubit graph-state preparation unitaries, which we treat as elementary building blocks. Specifically, we consider a one-dimensional chain of $N$ qubits initialized in a product state and evolved by layers in which nonoverlapping length-$n$ blocks are placed at uniformly random positions with sparsity $\alpha$. We find that different choices of graph-state building blocks lead to strongly varying dynamical rates. Graph states that are inequivalent under local Clifford (LC) transformations generate sharply different entanglement velocities $v_E$ and butterfly velocities $v_B$, even though the circuits are drawn from the same ensemble with identical architecture and randomness parameters. We further show that this hierarchy is captured by two complementary block-level characteristics: the distribution of entanglement across internal bipartitions of the graph state, which correlates with $v_E$, and a graph-theoretic connectivity profile across bipartitions, which correlates with $v_B$. Neither descriptor alone fully determines the dynamics; rather, entanglement growth and operator spreading are controlled by distinct structural features of the local circuit blocks. Notably, AME states appear among the fastest scrambling building blocks within the ensembles studied here.