Laser Beam Induced Charge Collection for Defect Mapping and Spin State Readout in Diamond

IF 4.4 Q1 OPTICS Advanced quantum technologies Pub Date : 2024-08-20 DOI:10.1002/qute.202400237
Dominic Reinhardt, Julia Heupel, Cyril Popov, Ralf Wunderlich
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Abstract

The detection of laser-induced photo-currents in diamond is shown with about 100 fA resolution in the pico- to nanoampere range. A micro-electronic approach enables to work without using lock-in techniques. For that purpose, a commercially available and low-cost precision integrating amplifier is utilized on a home-built printed circuit board. This technique is applied to three different diamond samples with different defect concentrations. Two ultra-pure diamond samples with shallow implanted defects, predominantly nitrogen-vacancy (NV) centers and substitutional nitrogen (P1 centers), are investigated. The third sample is an electron-irradiated type Ib diamond with a much higher intrinsic defect concentration. For all samples, spatially resolved photo-current maps as well as laser power and bias voltage-dependent measurements are recorded. Furthermore, photo-currents are successfully recorded without an applied bias voltage. Finally, the technique is used to perform continuous wave photoelectric detection of magnetic resonances (PDMR) using NV centers. The presented approach paves the way for time-resolved photo-current measurements of individual defects and pulsed PDMR measurements without lock-in technology.

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激光束诱导电荷收集用于金刚石缺陷绘图和自旋态读出
激光诱导的金刚石光电流的探测结果显示,在皮安至纳安范围内的分辨率约为 100 fA。采用微电子方法可以在不使用锁定技术的情况下工作。为此,我们在自制的印刷电路板上使用了一个市售的低成本精密积分放大器。该技术适用于三种不同缺陷浓度的金刚石样品。其中两个超纯金刚石样品具有浅层植入缺陷,主要是氮空位(NV)中心和置换氮(P1 中心)。第三个样品是经过电子辐照的 Ib 型金刚石,其内在缺陷浓度要高得多。对所有样品都记录了空间分辨光电流图以及激光功率和偏置电压测量值。此外,在没有施加偏置电压的情况下也能成功记录光电流。最后,该技术被用于利用 NV 中心进行连续波磁共振光电检测(PDMR)。所介绍的方法为单个缺陷的时间分辨光电流测量和无需锁定技术的脉冲 PDMR 测量铺平了道路。
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期刊最新文献
Front Cover: Laser Beam Induced Charge Collection for Defect Mapping and Spin State Readout in Diamond (Adv. Quantum Technol. 12/2024) Inside Front Cover: Numerical Investigation of a Coupled Micropillar - Waveguide System for Integrated Quantum Photonic Circuits (Adv. Quantum Technol. 12/2024) Back Cover: Purity-Assisted Zero-Noise Extrapolation for Quantum Error Mitigation (Adv. Quantum Technol. 12/2024) Issue Information (Adv. Quantum Technol. 12/2024) Issue Information (Adv. Quantum Technol. 11/2024)
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