Reducing inhomogeneous broadening of spin and optical transitions of nitrogen-vacancy centers in high-pressure, high-temperature diamond

IF 7.5 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Rémi Blinder, Yuliya Mindarava, Thai Hien Tran, Ali Momenzadeh, Sen Yang, Petr Siyushev, Hitoshi Sumiya, Kenji Tamasaku, Taito Osaka, Norio Morishita, Haruki Takizawa, Shinobu Onoda, Hideyuki Hara, Fedor Jelezko, Jörg Wrachtrup, Junichi Isoya
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Abstract

With their optical addressability of individual spins and long coherence time, nitrogen-vacancy (NV) centers in diamond are often called “atom-like solid spin-defects”. As observed with trapped atomic ions, quantum interference mediated by indistinguishable photons was demonstrated between remote NV centers. In high sensitivity DC magnetometry at room temperature, NV ensembles are potentially rivaling with alkali-atom vapor cells. However, local strain induces center-to-center variation of both optical and spin transitions of NV centers. Therefore, advanced engineering of diamond growth toward crystalline perfection is demanded. Here, we report on the synthesis of high-quality HPHT (high-pressure, high-temperature) crystals, demonstrating a small inhomogeneous broadening of the spin transitions, of T2* = 1.28 μs, approaching the limit for crystals with natural 13C abundance, that we determine as T2* = 1.48 μs. The contribution from strain and local charges to the inhomogeneous broadening is lowered to ~17 kHz full width at half maximum for NV ensemble within a > 10 mm3 volume. Looking at optical transitions in low nitrogen crystals, we examine the variation of zero-phonon-line optical transition frequencies at low temperatures, showing a strain contribution below 2 GHz for a large fraction of single NV centers. Nitrogen-vacancy centers in diamond offer a promising platform for quantum applications but their optical and spin properties can be hampered by imperfections of the host crystal. Here, nitrogen-vacancy centers are created in high-pressure high-temperature diamond of high crystalline quality, demonstrating a small inhomogeneous broadening of the spin and optical transitions.

Abstract Image

减少高压高温金刚石中氮空位中心自旋和光学转变的非均相展宽
金刚石中的氮空位(NV)中心具有单个自旋的光学可寻址性和长相干时间,通常被称为 "类原子固体自旋缺陷"。正如在被困的原子离子中观察到的那样,在遥远的 NV 中心之间,由不可分辨的光子介导的量子干涉已经得到证实。在室温下的高灵敏度直流磁测量中,NV 组合有可能与碱原子蒸汽电池相媲美。然而,局部应变会导致 NV 中心的光学和自旋转变在中心与中心之间发生变化。因此,需要对金刚石的生长进行先进的工程设计,以实现完美的结晶。在此,我们报告了高质量 HPHT(高压高温)晶体的合成过程,结果表明自旋跃迁的非均质拓宽很小,T2* = 1.28 μs,接近天然 13C 丰度晶体的极限,我们将其确定为 T2* = 1.48 μs。对于 10 立方毫米体积内的 NV 集合,应变和局部电荷对不均匀展宽的贡献降低到约 17 kHz 的半最大全宽。我们研究了低氮晶体中的光学转变,考察了零声子线光学转变频率在低温下的变化,结果表明,对于很大一部分单个 NV 中心,应变的贡献低于 2 GHz。金刚石中的氮空位中心为量子应用提供了一个前景广阔的平台,但其光学和自旋特性可能会受到主晶体缺陷的影响。在这里,氮空位中心是在高结晶质量的高压高温金刚石中产生的,显示了自旋和光学转变的微小不均匀拓宽。
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来源期刊
Communications Materials
Communications Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
12.10
自引率
1.30%
发文量
85
审稿时长
17 weeks
期刊介绍: Communications Materials, a selective open access journal within Nature Portfolio, is dedicated to publishing top-tier research, reviews, and commentary across all facets of materials science. The journal showcases significant advancements in specialized research areas, encompassing both fundamental and applied studies. Serving as an open access option for materials sciences, Communications Materials applies less stringent criteria for impact and significance compared to Nature-branded journals, including Nature Communications.
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