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Quantum Circuits with Classically Simulable Operator Scrambling.

Mike Blake1, Noah Linden1

  • 1School of Mathematics, University of Bristol, Fry Building, Woodland Road, Bristol BS8 1UG, United Kingdom.

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|August 4, 2020
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Summary
This summary is machine-generated.

We introduce super-Clifford circuits that enable classical simulation of quantum operator scrambling. These circuits demonstrate that classical simulability does not preclude quantum scrambling, even in large qubit systems.

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Area of Science:

  • Quantum information science
  • Quantum computation
  • Quantum complexity theory

Background:

  • Quantum scrambling describes how quantum information spreads and becomes locally inaccessible.
  • Classical simulability of quantum systems is generally believed to be limited, especially for systems exhibiting scrambling.
  • Understanding the boundary between classical and quantum computational power is a key challenge.

Purpose of the Study:

  • To introduce a new class of quantum circuits, termed super-Clifford circuits.
  • To demonstrate that certain aspects of quantum scrambling can be classically simulated.
  • To challenge the conventional understanding that classical simulability implies the absence of quantum scrambling.

Main Methods:

  • Developing a novel family of quantum circuits (super-Clifford circuits).
  • Analyzing the Heisenberg time evolution of nonlocal operators within these circuits.
  • Mapping operator evolution to Clifford evolution in an enlarged operator space.

Main Results:

  • Super-Clifford circuits allow for classically simulating the scrambling of a specific subspace of nonlocal operators.
  • The time evolution of single Pauli strings results in operators with linearly growing operator entanglement.
  • This linear growth of entanglement is observable even in systems with a large number of qubits.

Conclusions:

  • Super-Clifford circuits provide a new, efficient technique for studying quantum scrambling.
  • These circuits serve as explicit counterexamples to the intuition linking classical simulability and the absence of scrambling.
  • The findings open new avenues for exploring quantum complexity and the limits of classical simulation.