Spin measurements of NV centers coupled to a photonic crystal cavity

Jung, Thomas; Görlitz, Johannes; Kambs, Benjamin; Pauly, Christoph; Raatz, Nicole; Nelz, Richard; Neu, Elke; Edmonds, Andrew M.; Markham, Matthew; Mücklich, Frank; Meijer, Jan; Becher, Christoph

doi:10.1063/1.5120120

Cited by 20 publications

(21 citation statements)

References 89 publications

(125 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…First, single ions can be trapped easily for weeks and, thus, offer a much longer storage than that of single neutral atoms. [131] Second, the state of trapped ions can be detected near-deterministically by optical 171 Yb + . The transition 2 S 1∕2 to 2 P 1∕2 is pumped by a light with the wavelength of 369.5 nm.…”

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

“…[142] After the preparation of single ion-single photon entanglement, the photon can be used as a quantum bus to connect different nodes containing ions. In this spirit, in 2007, Moehring et al demonstrated the entanglement generation between two separated 171 Yb + . [143] In their experiment, two ions were trapped in two vacuum chambers separated by 1 m. The experimental apparatus is displayed in Figure 8.…”

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

“…[#0143], there were several experiments carried out with two separated trapped 171 Yb + ions and their nonclassical correlated photons. [144][145][146][147] In 2008, Matsukevich et al demonstrated the entanglement between two 171 Yb + ions separated by 1 m and further verified Bell inequality violation with ion-ion entanglement. [144] The experiment in ref.…”

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

“…Due to the experimental repetition of 75 kHz, the successful teleportation rate was about 0.083 per minute. At the same year, Maunz et al performed a heralded quantum gate between remote quantum memories consisting of single 171 Yb + ions and entangled them together [146] . The maximum efficiency of entangling gate generation was about 4.2 × 10 −8 .…”

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

See 3 more Smart Citations

Towards Real‐World Quantum Networks: A Review

Wei

Jing

Zhang

et al. 2022

Laser & Photonics Reviews

View full text Add to dashboard Cite

Quantum networks play an extremely important role in quantum information science, with application to quantum communication, computation, metrology, and fundamental tests. One of the key challenges for implementing a quantum network is to distribute entangled flying qubits to spatially separated nodes, at which quantum interfaces or transducers map the entanglement onto stationary qubits. The stationary qubits at the separated nodes constitute quantum memories realized in matter while the flying qubits constitute quantum channels realized in photons. Dedicated efforts around the world for more than 20 years have resulted in both major theoretical and experimental progress toward entangling quantum nodes and ultimately building a global quantum network. Here, the development of quantum networks and the experimental progress over the past two decades leading to the current state of the art for generating entanglement of quantum nodes based on various physical systems such as single atoms, cold atomic ensembles, trapped ions, diamonds with nitrogen-vacancy centers, and solid-state host doped with rare-earth ions are reviewed. Along the way, the merits are discussed and the potential of each of these systems toward realizing a quantum network is compared.

show abstract

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

Section: Quantum Network With Trapped Ionsmentioning

confidence: 99%

See 2 more Smart Citations

Towards Real‐World Quantum Networks: A Review

Wei

Jing

Zhang

et al. 2022

Laser & Photonics Reviews

View full text Add to dashboard Cite

show abstract

“…It is challenging to inhibit the phonon relaxation process and improve the photon emission efficiency via the ZPL. One approach is to couple the NV centers to cavities so as to enhance the ZPL via the Purcell effect [167,168].…”

Section: Quantum Network With Nitrogen-vacancy Center In Diamondsmentioning

confidence: 99%

Towards real-world quantum networks: a review

Wei,

Jing,

Zhang

et al. 2022

Preprint

View full text Add to dashboard Cite

Quantum networks play an extremely important role in quantum information science, with application to quantum communication, computation, metrology and fundamental tests. One of the key challenges for implementing a quantum network is to distribute entangled flying qubits to spatially separated nodes, at which quantum interfaces or transducers map the entanglement onto stationary qubits. The stationary qubits at the separated nodes constitute quantum memories realized in matter while the flying qubits constitute quantum channels realized in photons. Dedicated efforts around the world for more than twenty years have resulted in both major theoretical and experimental progress towards entangling quantum nodes and ultimately building a global quantum network. Here, we review the development of quantum networks and the experimental progress over the past two decades leading to the current state of the art for generating entanglement of quantum nodes based on various physical systems such as single atoms, cold atomic ensembles, trapped ions, diamonds with Nitrogen-Vacancy centers, solid-state host doped with rare-earth ions, etc. Along the way we discuss the merits and compare the potential of each of these systems towards realizing a quantum network.

show abstract

Robotic Vectorial Field Alignment for Spin‐Based Quantum Sensors

Smith,

Zhang,

Balram

2023

Advanced Science

View full text Add to dashboard Cite

Developing practical quantum technologies will require the exquisite manipulation of fragile systems in a robust and repeatable way. As quantum technologies move toward real world applications, from biological sensing to communication in space, increasing experimental complexity introduces constraints that can be alleviated by the introduction of new technologies. Robotics has shown tremendous progress in realizing increasingly smart, autonomous, and highly dexterous machines. Here, a robotic arm equipped with a magnet is demonstrated to sensitize an NV center quantum magnetometer in challenging conditions unachievable with standard techniques. Vector magnetic fields are generated with 1° angular and 0.1 mT amplitude accuracy and determine the orientation of a single stochastically‐aligned spin‐based sensor in a constrained physical environment. This work opens up the prospect of integrating robotics across many quantum degrees of freedom in constrained settings, allowing for increased prototyping speed, control, and robustness in quantum technology applications.

show abstract

Spin measurements of NV centers coupled to a photonic crystal cavity

Cited by 20 publications

References 89 publications

Towards Real‐World Quantum Networks: A Review

Towards Real‐World Quantum Networks: A Review

Towards real-world quantum networks: a review

Robotic Vectorial Field Alignment for Spin‐Based Quantum Sensors

Contact Info

Product

Resources

About