Single Nitrogen Vacancy(单一氮空位)研究综述
Single Nitrogen Vacancy 单一氮空位 - We develop a parallel optically detected magnetic resonance (PODMR) spectrometer to address, manipulate, and read out an array of single nitrogen-vacancy (NV) centers in diamond in parallel. [1] To this end, we perform nanoscale, all-optical relaxometry with a scanning quantum sensor based on a single nitrogen-vacancy (NV) defect in diamond. [2] , "A robust scanning diamond sensor for nanoscale imaging with single nitrogen-vacancy centres", Nat. [3] We propose what we believe is a novel proposal for realizing a quantum C-NOT logic gate, through fabricating an interesting hybrid device with a chiral photon-pulse switch, a single nitrogen-vacancy (NV) center, and an optical microcavity. [4] Here we experimentally demonstrate dynamically encircling the exceptional point with a single nitrogen-vacancy center in diamond. [5] In this letter, the photon-induced charge conversion dynamics of a single Nitrogen-Vacancy (NV) center in nanodiamond between two charge states, negative (NV−) and neutral (NV0), is studied by the auto-correlation function. [6] We transfer a pre-characterized nanodiamond with a single nitrogen-vacancy (NV) center onto an epitaxial silver substrate and deterministically couple it to a nanopatch antenna. [7] Moreover, the DL discrimination scheme outperform Bayesian methods when verified on noisy experimental data obtained by a single Nitrogen-Vacancy (NV) center. [8] We present high-resolution optically detected magnetic resonance (ODMR) spectroscopy on single nitrogen-vacancy (NV) center spins in diamond at and around zero magnetic field. [9] This allowed them to investigate PT-symmetric physics with a single nitrogen-vacancy center in diamond. [10] We present and analyze a hybrid quantum system that interfaces a Majorana-hosted semiconductor nanowire with a single nitrogen-vacancy (NV) center via a magnetized torsional cantilever. [11] We demonstrate detection of arbitrary waveforms with $\sim 20 {\rm ns}$ time resolution and $\sim 4\mu{\rm T}/\sqrt{\rm Hz}$ field sensitivity using the electronic spin of a single nitrogen-vacancy center in diamond. [12] Among quantum sensors, the single nitrogen-vacancy (NV) defect in diamond has the highest sensitivity-to-size factor. [13] The proposed launchers contain single nitrogen-vacancy (NV) centers in nanodiamonds as quantum emitters that offer record-high average fluorescence lifetime shortening factors of about 7000 times. [14] This allowed them to investigate PT-symmetric physics with a single nitrogen-vacancy center in diamond. [15] We present an experimental demonstration of a dressed state generated by two-photon magnetic resonances using a single spin in a single nitrogen-vacancy center in diamond. [16] We demonstrate a technique for highly controllable assembly of single-photon sources coupled to plasmonic nanoantennas with optimal emitter positioning on the nanoscale, resulting in fluorescence decay rates beyond 10 GHz in single nitrogen-vacancy centers. [17] We transfer a pre-characterized nanodiamond with a single nitrogen-vacancy (NV) center onto an epitaxial silver substrate and deterministically couple it to a nanopatch antenna. [18] We demonstrate a technique for highly controllable assembly of single-photon sources coupled to plasmonic nanoantennas with optimal emitter positioning on the nanoscale, resulting in fluorescence decay rates beyond 10 GHz in single nitrogen-vacancy centers. [19] Here, we present experimental results on the GPW mode excitation in a gap between a monocrystalline silver nanowire and a monocrystalline silver flake by using a single nitrogen-vacancy center in a nanodiamond. [20] Here, we experimentally demonstrate an adaptive method to learn the effective Hamiltonian of an 11-qubit quantum system consisting of one electron spin and ten nuclear spins associated with a single Nitrogen-Vacancy center in a diamond. [21] The working principle is based on the measurement of the resonance frequency shift of a single nitrogen-vacancy center (or an ensemble of them), usually detected by by monitoring the center photoluminescence emission intensity. [22]我们开发了一种平行的光学检测磁共振 (PODMR) 光谱仪,以并行处理、操作和读出金刚石中的单个氮空位 (NV) 中心阵列。 [1] 为此,我们使用基于金刚石中单个氮空位 (NV) 缺陷的扫描量子传感器进行纳米级全光学弛豫测量。 [2] ,“用于具有单个氮空位中心的纳米级成像的强大扫描金刚石传感器”,Nat。 [3] 我们提出了我们认为是实现量子 C-NOT 逻辑门的新方案,通过制造具有手性光子脉冲开关、单个氮空位 (NV) 中心和光学微腔的有趣混合器件。 [4] 在这里,我们通过实验证明用金刚石中的单个氮空位中心动态环绕异常点。 [5] 在这封信中,通过自相关函数研究了纳米金刚石中单个氮空位 (NV) 中心在负 (NV-) 和中性 (NV0) 两种电荷状态之间的光子诱导电荷转换动力学。 [6] nan [7] nan [8] nan [9] nan [10] nan [11] nan [12] nan [13] nan [14] nan [15] nan [16] nan [17] nan [18] nan [19] nan [20] nan [21] nan [22]