High-fidelity projective read-out of a solid-state spin quantum register

Solid-state spin defects are a promising platform for quantum science and technology. The realization of larger-scale quantum systems with solid-state defects will require high-fidelity control over multiple defects with nanoscale separations, with strong spin-spin interactions for multi-qubit logic operations and the creation of entangled states. We demonstrate an optical frequency-domain multiplexing technique, allowing high-fidelity initialization and single-shot spin measurement of six rare-earth (Er3+) ions, within the subwavelength volume of a single, silicon photonic crystal cavity. We also demonstrate subwavelength control over coherent spin rotations by using an optical AC Stark shift. Our approach may be scaled to large numbers of ions with arbitrarily small separation and is a step toward realizing strongly interacting atomic defect ensembles with applications to quantum information processing and fundamental studies of many-body dynamics.

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Cavity-enhanced microwave readout of a solid-state spin sensor

Nature Communications ◽

10.1038/s41467-021-21256-7 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Erik R. Eisenach ◽

John F. Barry ◽

Michael F. O’Keeffe ◽

Jennifer M. Schloss ◽

Matthew H. Steinecker ◽

...

Keyword(s):

Solid State ◽

Quantum Electrodynamics ◽

Cavity Quantum Electrodynamics ◽

Nitrogen Vacancy ◽

Microwave Cavity ◽

High Fidelity ◽

Collective Interaction ◽

Nitrogen Vacancy Centers ◽

State Spin ◽

Nyquist Noise

AbstractOvercoming poor readout is an increasingly urgent challenge for devices based on solid-state spin defects, particularly given their rapid adoption in quantum sensing, quantum information, and tests of fundamental physics. However, in spite of experimental progress in specific systems, solid-state spin sensors still lack a universal, high-fidelity readout technique. Here we demonstrate high-fidelity, room-temperature readout of an ensemble of nitrogen-vacancy centers via strong coupling to a dielectric microwave cavity, building on similar techniques commonly applied in cryogenic circuit cavity quantum electrodynamics. This strong collective interaction allows the spin ensemble’s microwave transition to be probed directly, thereby overcoming the optical photon shot noise limitations of conventional fluorescence readout. Applying this technique to magnetometry, we show magnetic sensitivity approaching the Johnson–Nyquist noise limit of the system. Our results pave a clear path to achieve unity readout fidelity of solid-state spin sensors through increased ensemble size, reduced spin-resonance linewidth, or improved cavity quality factor.

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Universal, high-fidelity quantum gates based on superadiabatic, geometric phases on a solid-state spin-qubit at room temperature

npj Quantum Information ◽

10.1038/s41534-018-0098-7 ◽

2018 ◽

Vol 4 (1) ◽

Cited By ~ 14

Author(s):

Felix Kleißler ◽

Andrii Lazariev ◽

Silvia Arroyo-Camejo

Keyword(s):

Solid State ◽

Room Temperature ◽

Quantum Gates ◽

High Fidelity ◽

Geometric Phases ◽

Spin Qubit ◽

State Spin

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Room temperature high-fidelity holonomic single-qubit gate on a solid-state spin

Nature Communications ◽

10.1038/ncomms5870 ◽

2014 ◽

Vol 5 (1) ◽

Cited By ~ 109

Author(s):

Silvia Arroyo-Camejo ◽

Andrii Lazariev ◽

Stefan W. Hell ◽

Gopalakrishnan Balasubramanian

Keyword(s):

Solid State ◽

Room Temperature ◽

High Fidelity ◽

Single Qubit ◽

State Spin ◽

Qubit Gate

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A phononic interface between a superconducting quantum processor and quantum networked spin memories

npj Quantum Information ◽

10.1038/s41534-021-00457-4 ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

Tomáš Neuman ◽

Matt Eichenfield ◽

Matthew E. Trusheim ◽

Lisa Hackett ◽

Prineha Narang ◽

...

Keyword(s):

Quantum State ◽

Piezoelectric Transducers ◽

High Fidelity ◽

Hybrid Architecture ◽

Quantum Networks ◽

Superconducting Circuit ◽

Artificial Atom ◽

Experimental Parameters ◽

Quantum Processor ◽

State Spin

AbstractWe introduce a method for high-fidelity quantum state transduction between a superconducting microwave qubit and the ground state spin system of a solid-state artificial atom, mediated via an acoustic bus connected by piezoelectric transducers. Applied to present-day experimental parameters for superconducting circuit qubits and diamond silicon-vacancy centers in an optimized phononic cavity, we estimate quantum state transduction with fidelity exceeding 99% at a MHz-scale bandwidth. By combining the complementary strengths of superconducting circuit quantum computing and artificial atoms, the hybrid architecture provides high-fidelity qubit gates with long-lived quantum memory, high-fidelity measurement, large qubit number, reconfigurable qubit connectivity, and high-fidelity state and gate teleportation through optical quantum networks.

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