Dynamical sensitivity control of a single-spin quantum sensor

Lazariev, Andrii; Arroyo-Camejo, Silvia; Rahane, Ganesh; Kavatamane, Vinaya Kumar; Balasubramanian, Gopalakrishnan

doi:10.1038/s41598-017-05387-w

Cited by 9 publications

(14 citation statements)

References 55 publications

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“…However, such measurements are often complicated by nonidealities in certain sequences' filter functions, such as sensitivity to harmonics or the presence of side lobes (Cywiński et al, 2008). Recently, ac magnetometry protocols with enhanced spectral resolution have been demonstrated, such as the dynamic sensitivity control (known as DYSCO) sequence and its variants (Lazariev et al, 2017;Romach et al, 2019), which provide simpler, single-peaked filter functions at the cost of reduced sensitivity. Additional dynamical decoupling sequences with increased spectral resolution or other advantages have been employed (Boss et al, 2017;Schmitt et al, 2017;Glenn et al, 2018;Hernández-Gómez et al, 2018) or proposed (Cywiński et al, 2008;Zhao, Wrachtrup, and Liu, 2014;Poggiali, Cappellaro, and Fabbri, 2018).…”

Section: A Dynamical Decoupling For Ac Magnetometrymentioning

confidence: 99%

Sensitivity optimization for NV-diamond magnetometry

et al. 2020

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Solid-state spin systems including nitrogen-vacancy (NV) centers in diamond constitute an increasingly favored quantum sensing platform. However, present NV ensemble devices exhibit sensitivities orders of magnitude away from theoretical limits. The sensitivity shortfall both handicaps existing implementations and curtails the envisioned application space. This review analyzes present and proposed approaches to enhance the sensitivity of broadband ensemble-NV-diamond magnetometers. Improvements to the spin dephasing time, the readout fidelity, and the host diamond material properties are identified as the most promising avenues and are investigated extensively. This analysis of sensitivity optimization establishes a foundation to stimulate development of new techniques for enhancing solid-state sensor performance.

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Section: A Dynamical Decoupling For Ac Magnetometrymentioning

confidence: 99%

Sensitivity optimization for NV-diamond magnetometry

et al. 2020

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“…Dynamical decoupling schemes are based on π pulse trains which command the spin precession abruptly. Recently, dynamical sensitivity control (DYSCO) has been proposed, aiming to provide smooth and analog sensitivity modulation [25]. In this control method, |2π| ambiguities are removed without sacrificing accuracy.…”

Section: Reviewmentioning

confidence: 99%

Nitrogen-vacancy centers in diamond for nanoscale magnetic resonance imaging applications

Boretti¹,

Rosa²,

Blackledge³

et al. 2019

Beilstein J. Nanotechnol.

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The nitrogen-vacancy (NV) center is a point defect in diamond with unique properties for use in ultra-sensitive, high-resolution magnetometry. One of the most interesting and challenging applications is nanoscale magnetic resonance imaging (nano-MRI). While many review papers have covered other NV centers in diamond applications, there is no survey targeting the specific development of nano-MRI devices based on NV centers in diamond. Several different nano-MRI methods based on NV centers have been proposed with the goal of improving the spatial and temporal resolution, but without any coordinated effort. After summarizing the main NV magnetic imaging methods, this review presents a survey of the latest advances in NV center nano-MRI.

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“…Their improvement of the dynamic range compared to a sequence with 16 π-pulses was about 26, and they explored the effect of the phase of the measured field in depth. Besides, one of the advantages of the previously reported dynamical sensitivity control 11 was the increase in the range by 4000 times, up to a theoretical maximum of 5000 times. Their uncertainty for a single measurement was about double that of a similar standard measurement, while the required multi-measurement for the large range worsened the sensitivity further (which is the uncertainty times ) by with N ϕ the number of phases applied in their method (the more phases, the larger the range, but each phase requires an additional measurement).…”

Section: Introductionmentioning

confidence: 96%

“…For quantum-sensing applications, nitrogen-vacancy (NV) centres in diamond have attracted considerable attention due to their exceptional quantummechanical properties 1,2 , including long spin-coherence times 3,4 , and due to their great potential for far-field optical nanoscopy [5][6][7][8] . Furthermore, an increase in sensitivity can be gained for alternating current (AC) field sensing by prolonging the NV spin coherence with dynamical decoupling of the centre's spin from its environment 2,3,[9][10][11][12] . Therefore, AC field sensing is applied in various areas of physics, chemistry and biology: to detect single spins [13][14][15] , for nuclear magnetic-resonance of tiny samplevolumes [16][17][18][19][20] , for nanoscale magnetic-resonance imaging 13,[21][22][23] and to search for new particles beyond the standard model 24,25 .…”

mentioning

confidence: 99%

Ultra-high dynamic range quantum measurement retaining its sensitivity

et al. 2021

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Quantum sensors are highly sensitive since they capitalise on fragile quantum properties such as coherence, while enabling ultra-high spatial resolution. For sensing, the crux is to minimise the measurement uncertainty in a chosen range within a given time. However, basic quantum sensing protocols cannot simultaneously achieve both a high sensitivity and a large range. Here, we demonstrate a non-adaptive algorithm for increasing this range, in principle without limit, for alternating-current field sensing, while being able to get arbitrarily close to the best possible sensitivity. Therefore, it outperforms the standard measurement concept in both sensitivity and range. Also, we explore this algorithm thoroughly by simulation, and discuss the T−2 scaling that this algorithm approaches in the coherent regime, as opposed to the T−1/2 of the standard measurement. The same algorithm can be applied to any modulo-limited sensor.

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Dynamical sensitivity control of a single-spin quantum sensor

Cited by 9 publications

References 55 publications

Sensitivity optimization for NV-diamond magnetometry

Sensitivity optimization for NV-diamond magnetometry

Nitrogen-vacancy centers in diamond for nanoscale magnetic resonance imaging applications

Ultra-high dynamic range quantum measurement retaining its sensitivity

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