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Cat qubit quantum chips use superconducting circuits to generate, stabilize, and control cat qubits.

A cat qubit quantum computer is one proposed approach to a large-scale quantum computer based on Schrödinger cat states.

Cat states are superpositions of two coherent states of light. Cat qubits encode quantum information in these states.[1]

They are designed to provide built in protection against certain types of errors, particularly bit flips, making quantum error correction more efficient in superconducting circuits.[2]

The approach is being developed by Alice & Bob and Amazon Web Services (AWS), among others.[3][4]

Background

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Cat qubits use coherent states of a quantum harmonic oscillator—microwave photons trapped in a superconducting resonator—as their logical 0 and 1 states.[1] The name derives from the Schrödinger's cat thought experiment, in which a system exists in a superposition of two macroscopically distinct states.[3]

Errors in quantum computation generally occur as bit-flip errors — changing a qubit's logical state from 0 to 1 or vice versa — and phase-flip errors, which alter the relative phase between superposed states.[2][4]

The key property of cat qubits is that the probability of a bit-flip decreases exponentially with the number of photons in the coherent state.[1] In conventional superconducting transmon-based architectures using surface codes, correcting both types of errors can require a significant number of physical qubits to realize a single error-free logical qubit.[2]

Cat qubits can be stabilized against bit-flip errors by coupling the qubit to an environment that preferentially exchanges pairs of photons with the system. This autonomously counteracts the effects of some errors that generate bit-flips and ensures that the quantum state remains within the desired error-corrected subspace.[5]

The intrinsic suppression of bit flips means that error correction only needs to address one dominant error channel, a property known as a noise-bias. This allows for the use of one-dimensional error correction codes, such as the classical repetition code, rather than two-dimensional surface codes.[6]

As a result, cat qubits could encode a logical qubit in a more hardware-efficient architecture to enable a universal set of fully protected logical operations while avoiding the significant overhead required by other error-correcting codes.[6]

This design suggests that cat qubits demonstrate the potential to efficiently scale to full error correction and fault tolerant quantum computing.[5][7]

History

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Cat qubits were first proposed as the building blocks for a universal fault-tolerant quantum computer in 2001.[8]

In 2015, Devoret et al. published the first experimental demonstration of cat qubits.[9][10]

In 2020, cat qubits in an oscillator exponentially suppressed bit-flips, demonstrating the potential for quantum computation with reduced overhead.[11]

In 2024, Alice & Bob researchers extended the bit-flip lifetime – the duration a qubit can maintain its state before it experiences a bit-flip error – to seven minutes.[12][13]

In 2025, AWS developed a chip that demonstrated a 1.65% per cycle for a five-cat qubit array.[3][14] Achieving this degree of error suppression with larger error-correcting codes previously required tens of additional qubits. However, the chip still needs to address both bit-flip and phase-flip errors as it incorporates both transmons and cat qubits.[2]

References

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  1. ^ a b c Cottet, Nathanaël (6 Nov 2023). "Encoding quantum information in states of light". Laser Focus World. Retrieved 2025-09-15.
  2. ^ a b c d Boerkamp, Martijn (6 Nov 2023). "Cat qubits open a faster track to fault-tolerant quantum computing". Physics World. Retrieved 2025-09-15.
  3. ^ a b c Vallance, Chris (27 Feb 2025). "Amazon joins quantum race with 'cat qubit' powered chip". Physics World. Retrieved 2025-09-15.
  4. ^ a b Russell, John (6 Nov 2023). "What is a Cat Qubit and Why Should You Care? Ask Alice & Bob". HPCwire. Retrieved 2025-09-15.
  5. ^ a b Schlegel, David (5 Mar 2024). "Cat qubits reach a new level of stability". Physics World. Retrieved 2025-09-16.
  6. ^ a b Guillaud, Jérémie; Mirrahimi, Mazyar (2019-12-12). "Repetition Cat Qubits for Fault-Tolerant Quantum Computation". Physical Review X. 9 (4) 041053. arXiv:1904.09474. doi:10.1103/PhysRevX.9.041053.
  7. ^ Nature Publishing Group. "How Schrödinger's cat could help improve quantum computers". Phys.org. Retrieved 2025-09-16.
  8. ^ California Institute of Technology (5 Mar 2025). "Quantum Computing's Biggest Problem? The Ocelot Chip Might Finally Solve It". SciTechDaily. Retrieved 2025-09-16.
  9. ^ Devoret, Michel H.; Leghtas, Zaki (2015-02-20). "Confining the state of light to a quantum manifold by engineered two-photon loss". Science. 347 (6224): 853–857. arXiv:1412.4633. doi:10.1126/science.aaa2085.
  10. ^ Swayne, Matt (13 Oct 2021). "TQD Exclusive with Michel Devoret: Alice and Bob's New Scientific Advisor Hopes Quantum Science Leads to Practical Applications". The Quantum Insider. Retrieved 2025-09-16.
  11. ^ Lescanne, Raphaël; Villiers, Marius; Peronnin, Théau; Sarlette, Alain; Delbecq, Matthieu; Huard, Benjamin; Kontos, Takis; Mirrahimi, Mazyar; Leghtas, Zaki (2020-03-16). "Exponential suppression of bit-flips in a qubit encoded in an oscillator". Nature. 16 (5): 509–513. arXiv:1907.11729. doi:10.1038/s41567-019-0714-5.
  12. ^ Riley, Duncan (15 May 2024). "Alice & Bob brings fault-tolerant Boson cat qubit quantum chip to Google Cloud Marketplace". The Quantum Insider. Retrieved 2025-09-17.
  13. ^ Roundy, Jacob (28 Mar 2025). "12 companies building quantum computers". SiliconANGLE. Retrieved 2025-09-17.
  14. ^ Putterman, Harald; Noh, Kyungjoo; Hann, Connor T.; MacCabe, Gregory S.; Aghaeimeibodi, Shahriar; Patel, Rishi N.; Lee, Menyoung; Jones, William M.; Moradinejad, Hesam; Rodriguez, Roberto; Mahuli, Neha; Rose, Jefferson; Owens, John Clai; Levine, Harry; Rosenfeld, Emma; Reinhold, Philip; Moncelsi, Lorenzo; Alcid, Joshua Ari; Alidoust, Nasser; Arrangoiz‑Arriola, Patricio; Barnett, James; Bienias, Przemyslaw; Carson, Hugh A.; Chen, Cliff (2025-02-26). "Hardware‑efficient quantum error correction via concatenated bosonic qubits". Nature. 638 (8052): 927–934. arXiv:2409.13025. doi:10.1038/s41586‑025‑08642‑7.
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