Quantum dot spin-photon entanglement and quantum teleportation from a Photon to a Solid-State Spin Qubit

Decoherence limits the physical realization of qubits, and its mitigation is critical for the development of quantum science and technology. We construct a robust qubit embedded in a decoherence-protected subspace, obtained by applying microwave dressing to a clock transition of the ground-state electron spin of a silicon carbide divacancy defect. The qubit is universally protected from magnetic, electric, and temperature fluctuations, which account for nearly all relevant decoherence channels in the solid state. This culminates in an increase of the qubit’s inhomogeneous dephasing time by more than four orders of magnitude (to >22 milliseconds), while its Hahn-echo coherence time approaches 64 milliseconds. Requiring few key platform-independent components, this result suggests that substantial coherence improvements can be achieved in a wide selection of quantum architectures.

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Room-Temperature Implementation of the Quantum Streaming Algorithm in a Single Solid-State Spin Qubit

Physical Review Applied ◽

10.1103/physrevapplied.16.024027 ◽

2021 ◽

Vol 16 (2) ◽

Author(s):

Fei-Fei Yan ◽

Zhen-Peng Xu ◽

Qiang Li ◽

Jun-Feng Wang ◽

Ji-Yang Zhou ◽

...

Keyword(s):

Solid State ◽

Room Temperature ◽

Streaming Algorithm ◽

Spin Qubit ◽

State Spin

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Fundamental limits of electron and nuclear spin qubit lifetimes in an isolated self-assembled quantum dot

npj Quantum Information ◽

10.1038/s41534-021-00378-2 ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

George Gillard ◽

Ian M. Griffiths ◽

Gautham Ragunathan ◽

Ata Ulhaq ◽

Callum McEwan ◽

...

Keyword(s):

Quantum Dot ◽

Spin Relaxation ◽

Nuclear Spin ◽

Operating Conditions ◽

External Control ◽

Spin Qubits ◽

Fundamental Limits ◽

Trade Offs ◽

Wide Range ◽

Spin Qubit

AbstractCombining external control with long spin lifetime and coherence is a key challenge for solid state spin qubits. Tunnel coupling with electron Fermi reservoir provides robust charge state control in semiconductor quantum dots, but results in undesired relaxation of electron and nuclear spins through mechanisms that lack complete understanding. Here, we unravel the contributions of tunnelling-assisted and phonon-assisted spin relaxation mechanisms by systematically adjusting the tunnelling coupling in a wide range, including the limit of an isolated quantum dot. These experiments reveal fundamental limits and trade-offs of quantum dot spin dynamics: while reduced tunnelling can be used to achieve electron spin qubit lifetimes exceeding 1 s, the optical spin initialisation fidelity is reduced below 80%, limited by Auger recombination. Comprehensive understanding of electron-nuclear spin relaxation attained here provides a roadmap for design of the optimal operating conditions in quantum dot spin qubits.

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