Random circuits with orthogonal or symplectic symmetry exhibit ternary Pauli weights, finite-width domain walls, and component-dependent butterfly velocities that can exceed the Haar value for q=2.
On the Complexity of Quantum States and Circuits from the Orthogonal and Symplectic Groups
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
Understanding the complexity of quantum states and circuits is a central challenge in quantum information science, with broad implications in many-body physics, high-energy physics and quantum learning theory. A common way to model the behaviour of typical states and circuits involves sampling unitary transformations from the Haar measure on the unitary group. In this work, we depart from this standard approach and instead study structured unitaries drawn from other compact connected groups, namely the symplectic and special orthogonal groups. By leveraging the concentration of measure phenomenon, we establish two main results. We show that random quantum states generated using symplectic or orthogonal unitaries typically exhibit an exponentially large strong state complexity, and are nearly orthogonal to one another. Similar behavior is observed for designs over these groups. Additionally, we demonstrate the average-case hardness of learning circuits composed of gates drawn from such classical groups of unitaries. Taken together, our results demonstrate that structured subgroups can exhibit a complexity comparable to that of the full unitary group.
fields
quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
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Operator spreading in random circuits with orthogonal or symplectic symmetry
Random circuits with orthogonal or symplectic symmetry exhibit ternary Pauli weights, finite-width domain walls, and component-dependent butterfly velocities that can exceed the Haar value for q=2.