Toward efficient fiber-based quantum interface (Conference Presentation)

SPIE Photonics Europe Pub Date : 2016-08-08 DOI:10.1117/12.2228692

V. Soshenko, V. Vorobyov, Stepan V. Bolshedvorsky, N. Lebedev, A. Akimov, V. Sorokin, A. Smolyaninov

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Abstract

NV center in diamond is attracting a lot of attention in quantum information processing community [1]. Been spin system in clean and well-controlled environment of diamond it shows outstanding performance as quantum memory even at room temperature, spin control with single shot optical readout and possibility to build up quantum registers even on single NV center. Moreover, NV centers could be used as high-resolution sensitive elements of detectors of magnetic or electric field, temperature, tension, force or rotation. For all of these applications collection of the light emitted by NV center is crucial point. There were number of approaches suggested to address this issue, proposing use of surface plasmoms [2], manufacturing structures in diamond [3] etc. One of the key feature of any practically important interface is compatibility with the fiber technology. Several groups attacking this problem using various approaches. One of them is placing of nanodiamonds in the holes of photonic crystal fiber [4], another is utilization of AFM to pick and place nanodiamond on the tapered fiber[5]. We have developed a novel technique of placing a nanodiamond with single NV center on the tapered fiber by controlled transfer of a nanodiamond from one “donor” tapered fiber to the “target” clean tapered fiber. We verify our ability to transfer only single color centers by means of measurement of second order correlation function. With this technique, we were able to double collection efficiency of confocal microscope. The majority of the factors limiting the collection of photons via optical fiber are technical and may be removed allowing order of magnitude improved in collection. We also discuss number of extensions of this technique to all fiber excitation and integration with nanostructures. References: [1] Marcus W. Doherty, Neil B. Manson, Paul Delaney, Fedor Jelezko, Jörg Wrachtrup, Lloyd C.L. Hollenberg , " The nitrogen-vacancy colour centre in diamond," Physics Reports, vol. 528, no. 1, p. 1–45, 2013. [2] A.V. Akimov, A. Mukherjee, C.L. Yu, D.E. Chang, A.S. Zibrov, P.R. Hemmer, H. Park and M.D. Lukin, "Generation of single optical plasmons in metallic nanowires coupled to quantum dots," Nature, vol. 450, p. 402–406, 2007. [3] Michael J. Burek , Yiwen Chu, Madelaine S.Z. Liddy, Parth Patel, Jake Rochman , Srujan Meesala, Wooyoung Hong, Qimin Quan, Mikhail D. Lukin and Marko Loncar High quality-factor optical nanocavities in bulk single-crystal diamond, Nature communications 6718 (2014) [4] Tim Schroder, Andreas W. Schell, Gunter Kewes, Thomas Aichele, and Oliver Benson Fiber-Integrated Diamond-Based Single Photon Source, Nano Lett. 2011, 11, 198-202 [5]Lars Liebermeister, et. al. “Tapered fiber coupling of single photons emitted by a deterministically positioned single nitrogen vacancy center”, Appl. Phys. Lett. 104, 031101 (2014)

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迈向高效光纤量子接口(会议报告)

金刚石中的NV中心在量子信息处理界备受关注[1]。该自旋系统在清洁、可控的金刚石环境中表现出优异的室温量子记忆性能、单次光学读出自旋控制性能和单次NV中心建立量子寄存器的可能性。此外，NV中心可作为磁场或电场、温度、张力、力或旋转探测器的高分辨率敏感元件。在所有这些应用中，收集NV中心发出的光是关键。有许多方法可以解决这个问题，如使用表面等离子体[2]、金刚石制造结构[3]等。任何实际重要接口的关键特征之一是与光纤技术的兼容性。有几个小组使用不同的方法来解决这个问题。一种是在光子晶体光纤的孔中放置纳米金刚石[4]，另一种是利用AFM在锥形光纤上拾取和放置纳米金刚石[5]。我们开发了一种新的技术，通过控制纳米金刚石从一个“供体”锥形纤维转移到“目标”干净的锥形纤维上，将具有单个NV中心的纳米金刚石放置在锥形纤维上。我们通过测量二阶相关函数来验证我们只传递单个色心的能力。该技术使共聚焦显微镜的采集效率提高了一倍。限制通过光纤收集光子的大多数因素是技术上的，可以消除，使收集的数量级得到改善。我们还讨论了该技术在所有纤维激发和与纳米结构集成方面的扩展。参考文献:[1]Marcus W. Doherty, Neil B. Manson, Paul Delaney, Fedor Jelezko, Jörg Wrachtrup, Lloyd C.L. Hollenberg，“钻石中的氮空位色中心”，物理报告，vol. 528, no. 1。1, p. 1 - 4, 2013。[2]张德德，刘志强，张德德，张志强，刘志强，“金属纳米线与量子点耦合的光等离子体激元的产生”，《光子学报》，vol. 45, p. 391 - 391, 2007。[3]朱一文，马德琳S.Z. Liddy, Michael J. Burek, Jake Rochman, Srujan Meesala，洪宇扬，全齐民，Mikhail D. Lukin, Marko Loncar，单晶金刚石的高质量因子光纳米腔，自然科学学报，2014，[4]Tim Schroder, Andreas W. Schell, Gunter Kewes, Thomas Aichele, Oliver Benson，光纤集成金刚石单光子源，2011,11,198-202“由确定定位的单氮空位中心发射的单光子的锥形光纤耦合”，苹果。理论物理。Lett. 104, 031101 (2014)

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