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Third Law of Thermodynamics and the Scaling of Quantum Computers

Lorenzo Buffoni, Stefano Gherardini, Emmanuel Zambrini Cruzeiro, Yasser Omar

2022INO Open Portal29 citationsDOI

Abstract

The third law of thermodynamics, also known as the Nernst unattainability principle, puts a fundamental bound on how close a system, whether classical or quantum, can be cooled to a temperature near to absolute zero. On the other hand, a fundamental assumption of quantum computing is to start each computation from a register of qubits initialized in a pure state, i.e., at zero temperature. These conflicting aspects, at the interface between quantum computing and thermodynamics, are often overlooked or, at best, addressed only at a single-qubit level. In this Letter, we argue how the existence of a small but finite effective temperature, which makes the initial state a mixed state, poses a real challenge to the fidelity constraints required for the scaling of quantum computers. Our theoretical results, carried out for a generic quantum circuit with N-qubit input states, are validated by test runs performed on a real quantum processor.

Topics & Concepts

Quantum computerQubitQuantum thermodynamicsPhysicsQuantumScalingQuantum algorithmSecond law of thermodynamicsQuantum mechanicsStatistical physicsComputer scienceMathematicsGeometryQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyAdvanced Thermodynamics and Statistical Mechanics
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