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1. Quantum control and Berry phase of electron spins in rotating levitated diamonds in high vacuum

   https://doi.org/10.1038/s41467-024-49175-3  

   Jin, Yuanbin; Shen, Kunhong; Ju, Peng; Gao, Xingyu; Zu, Chong; Grine, Alejandro_J; Li, Tongcang (June 2024, Nature Communications)

   Abstract Levitated diamond particles in high vacuum with internal spin qubits have been proposed for exploring macroscopic quantum mechanics, quantum gravity, and precision measurements. The coupling between spins and particle rotation can be utilized to study quantum geometric phase, create gyroscopes and rotational matter-wave interferometers. However, previous efforts in levitated diamonds struggled with vacuum level or spin state readouts. To address these gaps, we fabricate an integrated surface ion trap with multiple stabilization electrodes. This facilitates on-chip levitation and, for the first time, optically detected magnetic resonance measurements of a nanodiamond levitated in high vacuum. The internal temperature of our levitated nanodiamond remains moderate at pressures below 10⁻⁵Torr. We have driven a nanodiamond to rotate up to 20 MHz (1.2 × 10⁹rpm), surpassing typical nitrogen-vacancy (NV) center electron spin dephasing rates. Using these NV spins, we observe the effect of the Berry phase arising from particle rotation. In addition, we demonstrate quantum control of spins in a rotating nanodiamond. These results mark an important development in interfacing mechanical rotation with spin qubits, expanding our capacity to study quantum phenomena. 

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2. Single nuclear spin detection and control in a van der Waals material

   https://doi.org/10.1038/s41586-025-09258-7  

   Gao, Xingyu; Vaidya, Sumukh; Li, Kejun; Ge, Zhun; Dikshit, Saakshi; Zhang, Shimin; Ju, Peng; Shen, Kunhong; Jin, Yuanbin; Ping, Yuan; et al (July 2025, Nature)

   Abstract Optically active spin defects in solids^1,2are leading candidates for quantum sensing^3,4and quantum networking^5,6. Recently, single spin defects were discovered in hexagonal boron nitride (hBN)^7–11, a layered van der Waals (vdW) material. Owing to its two-dimensional structure, hBN allows spin defects to be positioned closer to target samples than in three-dimensional crystals, making it ideal for atomic-scale quantum sensing¹², including nuclear magnetic resonance (NMR) of single molecules. However, the chemical structures of these defects^7–11remain unknown and detecting a single nuclear spin with a hBN spin defect has been elusive. Here we report the creation of single spin defects in hBN using¹³C ion implantation and the identification of three distinct defect types based on hyperfine interactions. We observed bothS = 1/2 andS = 1 spin states within a single hBN spin defect. We demonstrated atomic-scale NMR and coherent control of individual nuclear spins in a vdW material, with a π-gate fidelity up to 99.75% at room temperature. By comparing experimental results with density functional theory (DFT) calculations, we propose chemical structures for these spin defects. Our work advances the understanding of single spin defects in hBN and provides a pathway to enhance quantum sensing using hBN spin defects with nuclear spins as quantum memories. 

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3. High-throughput assessment of the controllability of a nuclear-spin register coupled to a defect

   https://doi.org/10.1103/PhysRevApplied.22.054073  

   Dakis, Filippos; Takou, Evangelia; Barnes, Edwin; Economou, Sophia E (November 2024, Physical Review Applied)

   Quantum memories play a key role in facilitating tasks within quantum networks and quantum information processing, including secure communications, advanced quantum sensing, and distributed quantum computing. Progress in characterizing large nuclear-spin registers coupled to defect electronic spins has been significant, but selecting memory qubits remains challenging due to the multitude of possible assignments. Numerical simulations for evaluating entangling gate fidelities encounter obstacles, restricting research to small registers, while experimental investigations are time-consuming and often limited to well-understood samples. Here we present an efficient methodology for systematically assessing the controllability of defect systems coupled to nuclear-spin registers. We showcase the approach by investigating the generation of entanglement links between silicon monovacancy or divacancy centers in Si⁢C and randomly selected sets of nuclear spins within the two-species (13⁢C and 29⁢Si) nuclear register. We quantify the performance of entangling gate operations and present the achievable gate fidelities, considering both the size of the register and the presence of unwanted nuclear spins. We find that some control sequences perform better than others depending on the number of target versus bath nuclei. This efficient approach is a guide for both experimental investigation and engineering, facilitating the high-throughput exploration of suitable defect systems for quantum memories. 

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4. Demonstration of diamond nuclear spin gyroscope

   https://doi.org/10.1126/sciadv.abl3840  

   Jarmola, Andrey; Lourette, Sean; Acosta, Victor M.; Birdwell, A. Glen; Blümler, Peter; Budker, Dmitry; Ivanov, Tony; Malinovsky, Vladimir S. (October 2021, Science Advances)

   We demonstrate the operation of a rotation sensor based on the nitrogen-14 ( 14 N) nuclear spins intrinsic to nitrogen-vacancy (NV) color centers in diamond. The sensor uses optical polarization and readout of the nuclei and a radio-frequency double-quantum pulse protocol that monitors 14 N nuclear spin precession. This measurement protocol suppresses the sensitivity to temperature variations in the 14 N quadrupole splitting, and it does not require microwave pulses resonant with the NV electron spin transitions. The device was tested on a rotation platform and demonstrated a sensitivity of 4.7°/ s (13 mHz/ Hz ), with a bias stability of 0.4 °/s (1.1 mHz). 

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5. Spin Squeezing as a Probe of Emergent Quantum Orders

   https://doi.org/10.7566/JPSCP.38.011149  

   Nikolov, Ilija K.; Carr, Stephen; Del Maestro, Adrian G.; Ramanathan, Chandrasekhar; Mitrović, Vesna F. (May 2023, Proceedings of the 29th International Conference on Low Temperature Physics (LT29))

   Nuclear magnetic resonance (NMR) experiments can reveal local properties in materials, but are often limited by the low signal-to-noise ratio. Spin squeezed states have an improved resolution below the Heisenberg limit in one of the spin components, and have been extensively used to improve the sensitivity of atomic clocks, for example [1]. Interacting and entangled spin ensembles with non-linear coupling are a natural candidate for implementing squeezing. Here, we propose measurement of the spin-squeezing parameter that itself can act as a local probe of emergent orders in quantum materials. In particular, we demonstrate how to investigate an anisotropic electric field gradient via its coupling to the nuclear quadrupole moment. While squeezed spin states are pure, the squeezing parameter can be estimated for both pure and mixed states. We evaluate the range of fields and temperatures for which a thermal-equilibrium state is sufficient to improve the resolution in an NMR experiment and probe relevant parameters of the quadrupole Hamiltonian, including its anisotropy. 

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