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Dark Spin-Cat States as Biased Qubits.

Andreas Kruckenhauser1,2,3, Ming Yuan4, Han Zheng4

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|July 31, 2025
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Summary
This summary is machine-generated.

We introduce a "dark spin cat" atomic qubit, robust against noise and universally applicable. This qubit exhibits exponentially reduced bit-flip errors, enhancing quantum computing stability.

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Area of Science:

  • Quantum Computing
  • Atomic Physics
  • Quantum Information Science

Background:

  • Atomic qubits are crucial for quantum computation.
  • Current atomic qubit implementations face challenges with noise and error rates.
  • Developing robust and universally implementable qubits is a key research goal.

Purpose of the Study:

  • To present a novel biased atomic qubit design, the "dark spin cat."
  • To demonstrate the qubit's noise resilience and biased error characteristics.
  • To explore the implementation of quantum gates using this qubit architecture.

Main Methods:

  • Encoding a qubit in ground state Zeeman levels of atoms as a "spin cat."
  • Coupling ground and excited state spin manifolds using light.
  • Analyzing the properties of dark states immune to spontaneous emission and light coupling.
  • Investigating qubit stabilization under strong Rabi drive for large ground state manifold sizes (F_g).

Main Results:

  • Identification of two dark states in the ground state manifold, forming the "dark spin cat."
  • Autonomous stabilization of the dark spin cat against common noise sources.
  • Demonstration of a significantly biased qubit noise profile.
  • Exponential decrease in bit-flip error rate with increasing F_g relative to dephasing rate.

Conclusions:

  • The dark spin cat offers a robust and universally implementable atomic qubit.
  • The qubit exhibits inherent noise bias, favoring reduced bit-flip errors.
  • Bias-preserving single-qubit and entangling gates can be implemented, as shown on a Rydberg tweezer platform.