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Linear growth of quantum circuit complexity

Jonas Haferkamp, Philippe Faist, Naga Bhavya Teja Kothakonda, Jens Eisert, Nicole Yunger Halpern

2022Nature Physics152 citationsDOIOpen Access PDF

Abstract

Abstract The complexity of quantum states has become a key quantity of interest across various subfields of physics, from quantum computing to the theory of black holes. The evolution of generic quantum systems can be modelled by considering a collection of qubits subjected to sequences of random unitary gates. Here we investigate how the complexity of these random quantum circuits increases by considering how to construct a unitary operation from Haar-random two-qubit quantum gates. Implementing the unitary operation exactly requires a minimal number of gates—this is the operation’s exact circuit complexity. We prove a conjecture that this complexity grows linearly, before saturating when the number of applied gates reaches a threshold that grows exponentially with the number of qubits. Our proof overcomes difficulties in establishing lower bounds for the exact circuit complexity by combining differential topology and elementary algebraic geometry with an inductive construction of Clifford circuits.

Topics & Concepts

Quantum circuitQuantum gatePhysicsUnitary stateQuantum algorithmQuantum Turing machineTopology (electrical circuits)Quantum Fourier transformQuantum error correctionCircuit complexityQuantum computerQuantum networkQuantum mechanicsDiscrete mathematicsQuantumMathematicsElectronic circuitCombinatoricsLawPolitical scienceQuantum Computing Algorithms and ArchitectureComputability, Logic, AI AlgorithmsQuantum many-body systems
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