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Advances in Physics: X Volume 7, 2022 - Issue 1
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Inertial measurement with solid-state spins of nitrogen-vacancy center in diamond

Liye Zhaoa Key Laboratory of Micro-Inertial Instrument and Advanced Navigation Technology, Ministry of Education, School of Instrument Science and Engineering, Southeast University, Nanjing, CHINACorrespondence[email protected]
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Xiang Shena Key Laboratory of Micro-Inertial Instrument and Advanced Navigation Technology, Ministry of Education, School of Instrument Science and Engineering, Southeast University, Nanjing, CHINAORCID Iconhttps://orcid.org/0000-0003-3263-1862View further author information
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Lumin Jia Key Laboratory of Micro-Inertial Instrument and Advanced Navigation Technology, Ministry of Education, School of Instrument Science and Engineering, Southeast University, Nanjing, CHINAView further author information
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Pu Huangb School of Physics, Nanjing University, Nanjing, ChinaView further author information
Article: 2004921 | Received 18 Sep 2021, Accepted 06 Nov 2021, Published online: 11 Jan 2022

References

  • Zhang C, Yuan H, Tang Z, et al. Inertial rotation measurement with atomic spins: from angular momentum conservation to quantum phase theory. Appl Phys Rev. 2016 Dec;3:041305.
  • Yazdi N, Ayazi F, Najafi K. Micromachined inertial sensors. Proc IEEE. 1998 Aug;86:1640–20.
  • Rembold P, Oshnik N, Müller MM, et al. Introduction to quantum optimal control for quantum sensing with nitrogen-vacancy centers in diamond. AVS Quantum Sci. 2020 Jun;2:024701.
  • Taylor MA, Bowen WP. Quantum metrology and its application in biology. Phys Rep. 2016 Feb;615:1–59.
  • Taylor MA, Janousek J, Daria V, et al. Biological measurement beyond the quantum limit. Nat Photonics. 2013 Feb;7:229–233.
  • Morris PA, Aspden RS, Bell J, et al. Imaging with a small number of photons. Nat Commun. 2015 Jan;6:5913.
  • Hu Z-K, Sun B-L, Duan X-C, et al. Demonstration of an ultrahigh-sensitivity atom-interferometry absolute gravimeter. Phys Rev A. 2013 Oct;88:043610.
  • Demkowicz-Dobrzański R, Banaszek K, Schnabel R. Fundamental quantum interferometry bound for the squeezed-light-enhanced gravitational wave detector geo 600. Phys Rev A. 2013 Oct;88:041802.
  • Purdy TP, Peterson RW, Regal CA. Observation of radiation pressure shot noise on a macroscopic object. Science. 2013 Feb;339:801–804.
  • Adhikari RX. Gravitational radiation detection with laser interferometry. Rev Mod Phys. 2014 May;86:121–151.
  • Urbach E LISAO, Sushkov AO, Urbach E, et al. Nuclear magnetic resonance detection and spectroscopy of single proteins using quantum logic. Science. 2016 Feb;351:836–841.
  • Neumann P ANPM, Pfender M, Neumann P, et al. Nanoscale nuclear magnetic resonance with chemical resolution. Science. 2017 Jun;357:67–71.
  • Zhang T, Pramanik G, Zhang K, et al. Toward quantitative bio-sensing with nitrogen-vacancy center in diamond. ACS Sens. 2021 May.
  • Rong X, Lu D, Kong X, et al. Harnessing the power of quantum systems based on spin magnetic resonance: from ensembles to single spins. Adv Phys -X. 2017;2:125–168.
  • Zaiser S WGWY, Wang Y, Zaiser S, et al. Quantum error correction in a solid-state hybrid spin register. Nature. 2014 Feb;506:204–207.
  • Ying L XRGJSF, et al. Experimental fault-tolerant universal quantum gates with solid-state spins under ambient conditions. Nat Commun. 2015 Nov;6:8748.
  • Li Z XKXT, et al. Experimental adiabatic quantum factorization under ambient conditions based on a solid-state single spin system. Phys Rev Lett. 2017 Mar;118:130504.
  • Cong W, Bicak J, Kubiznak D, et al. Quantum detection of inertial frame dragging. Phys Rev D. 2021 Jan;103:024027.
  • Ju Z, Lin J, Shen S, et al. Preparations and applications of single color centers in the diamond. Adv Phys -X. 2021;6:1858721.
  • Shen X, Zhao L-Y, Huang P, et al. Atomic spin and phonon coupling mechanism of nitrogen-vacancy center. Acta Phys Sin. 2021 Mar;70:068501.
  • Wood AA, Lilette E, Fein YY, et al. Quantum measurement of a rapidly rotating spin qubit in diamond. Sci Adv. 2018 May;4:eaar7691.
  • Wood AA, Hollenberg LCL, Scholten RE, et al. Observation of a quantum phase from classical rotation of a single spin. Phys Rev Lett. 2020;124:020401.
  • Wood AA, Lilette E, Fein YY, et al. Magnetic pseudo-fields in a rotating electron-nuclear spin system. Nat Phys. 2017;13:1070–1074.
  • Chen X-Y, Yin Z-Q. High-precision gravimeter based on a nano-mechanical resonator hybrid with an electron spin. Opt Express. 2018;26:31577–31588. Nov, 26.
  • Gruber A, Dräbenstedt A, Tietz C, et al. Scanning confocal optical microscopy and magnetic resonance on single defect centers. Science. 1997 Jun;276:2012–2014.
  • Balasubramanian G, Neumann P, Twitchen D, et al. Ultralong spin coherence time in isotopically engineered diamond. Nat Mater. 2009 May;8:383–387.
  • Bar-Gill N, Pham LM, Jarmola A, et al. Solid-state electronic spin coherence time approaching one second. Nat Commun. 2013 Apr;4:1743.
  • Maze JR, Stanwix PL, Hodges JS, et al. Nanoscale magnetic sensing with an individual electronic spin in diamond. Nature. 2008 Oct;455:644–647.
  • Barry JF, Schloss JM, Bauch E, et al. Sensitivity optimization for NV-diamond magnetometry. Rev Mod Phys. 2020;92:015004.
  • Xie T, Zhao Z, Kong X, et al. Beating the standard quantum limit under ambient conditions with solid-state spins. Sci Adv. 2021 Aug;7:eabg9204.
  • Dolde F, Fedder H, Doherty MW, et al. Electric-field sensing using single diamond spins. Nat Phys. 2011 Jun;7:459–463.
  • Barfuss A, Teissier J, Neu E, et al. Strong mechanical driving of a single electron spin. Nat Phys. 2015 Oct;11:820–U185.
  • Sokolov K. Tiny thermometers used in living cells: nanotechnology. Nature. 2013 Aug;500:36–37.
  • Kucsko G, Maurer PC, Yao NY, et al. Nanometre-scale thermometry in a living cell. Nature. 2013;500:54–58.
  • Wang N, Liu G-Q, Leong W-H, et al. Magnetic criticality enhanced hybrid nanodiamond thermometer under ambient conditions. Phys Rev X. 2018;8:011042.
  • Chatzidrosos G, Wickenbrock A, Bougas L, et al. Miniature cavity-enhanced diamond magnetometer. Phys Rev Appl. 2017 Dec;8:044019.
  • Liu C-F, Leong W-H, Xia K, et al. Ultra-Sensitive hybrid diamond nanothermometer. Natl Sci Rev. 2021 Jun;8:nwaa194.
  • Maclaurin D, Doherty MW, Hollenberg LC, et al. Measurable quantum geometric phase from a rotating single spin. Phys Rev Lett. 2012 Jun;108:240403.
  • Ledbetter MP, Jensen K, Fischer R, et al. Gyroscopes based on nitrogen-vacancy centers in diamond. Phys Rev A. 2012 Nov;86:052116.
  • Ajoy A, Cappellaro P. Stable three-axis nuclear-spin gyroscope in diamond. Phys Rev A. 2012 May;86:062104.
  • Jarmola A, Lourette S, Acosta VM, et al. Demonstration of diamond nuclear spin gyroscope. Sci Adv. 2021 Oct;7:eabl3840.
  • Song X, Wang L, Feng F, et al. Nanoscale quantum gyroscope using a single 13C nuclear spin coupled with a nearby NV center in diamond[J]. J Appl Phys. 2018;123:114301.
  • Soshenko VV, Bolshedvorskii SV, Rubinas O, et al. Nuclear spin gyroscope based on the nitrogen vacancy center in diamond. Phys Rev Lett. 2021 May;126:197702.
  • Niebauer TM, Sasagawa GS, Faller JE, et al. A new generation of absolute gravimeters. Metrologia. 1995 Nov;32:159–180.
  • Merlet S, Bodart Q, Malossi N, et al. Comparison between two mobile absolute gravimeters: optical versus atomic interferometers. Metrologia. 2010 Aug;47:L9–L11.
  • Litterll KC, Allman BE, Werner SA. Two-wavelength-difference measurement of gravitationally induced quantum interference phases. Phys Rev A. 1997 Sep;56:1767–1780.
  • Abele H, Leeb H. Gravitation and quantum interference experiments with neutrons. New J Phys. 2012 May;14:1–5.
  • De Angelis M, Bertoldi A, Cacciapuoti L, et al. Precision gravimetry with atomic sensors. Meas Sci Technol. 2009 Feb;20:022001.
  • Bodart Q, Merlet S, Malossi N, et al. A cold atom pyramidal gravimeter with a single laser beam. Appl Phys Lett. 2010 Mar;96:849.
  • Zhang J, Chen L, Cheng Y, et al. Movable precision gravimeters based on cold atom interferometry. Chin Phys B. 2020 Sep;29:88–96.
  • Rademacher M, Millen J, Li YL. Quantum sensing with nanoparticles for gravimetry: when bigger is better. Adv Opt Technol. 2020 Oct;9:227–239.
  • Romero-isart O, Juan ML, Quidant R, et al. Toward quantum superposition of living organisms. New J Phys. 2010 Mar;12:033015.
  • Castelletto S, Rosa L, Boretti A. Micro-manipulation of nanodiamonds containing NV centers for quantum applications. Diam Relat Mat. 2020 Jun;106:107840.
  • Kumar P, Bhattacharya M. Magnetometry via spin-mechanical coupling in levitated optomechanics. Opt Express. 2017 Aug;25:19568–19582.
  • Rabl P, Kolkowitz SJ, Koppens FHL, et al. A quantum spin transducer based on nanoelectromechanical resonator arrays. Nat Phys. 2010 Aug;6:602–608.
  • Arcizet O, Jacques V, Siria A, et al. A single nitrogen-vacancy defect coupled to a nanomechanical oscillator. Nat Phys. 2011 Nov;7:879–883.
  • Rabl P, Cappellaro P, Dutt MVG, et al. Strong magnetic coupling between an electronic spin qubit and a mechanical resonator. Physical Review B. 2009 Jan;79:041302.
  • Kolkowitz S, Bleszynski Jayich AC, Unterreithmeier QP, et al. Coherent sensing of a mechanical resonator with a single-spin qubit. Science. 2012 Mar;335:1603–1606.
  • Xu ZY, Hu YM, Yang WL, et al. Deterministically entangling distant nitrogen-vacancy centers by a nanomechanical cantilever. Phys Rev A. 2009 Aug;80:2–5.
  • Zhou L-G, Wei LF, Gao M, et al. Strong coupling between two distant electronic spins via a nanomechanical resonator. Phys Rev A. 2010 Apr;81:1–5.
  • Ranjit G, Cunningham M, Casey K, et al. Zeptonewton force sensing with nanospheres in an optical lattice. Phys Rev A. 2016 May 93;93:053801.
  • Monteiro F, Ghosh S, Fine AG, et al. Optical levitation of 10-ng spheres with nano-g acceleration sensitivity. Phys Rev A. 2017 Dec;96:063841.
  • Millen J, Monteiro TS, Pettit R, et al. Optomechanics with levitated particles. Rep Prog Phys IOP Publishing. 2020;83:026401.
  • Yin Z-Q, Li T, Zhang X, et al. Large quantum superpositions of a levitated nanodiamond through spin-optomechanical coupling. Phys Rev A. 2013 Sep;88:033614.
  • Yin Z, Zhao N, Li T. Hybrid opto-mechanical systems with nitrogen-vacancy centers. Sci China Phys Mech Astron. 2015 Feb;58:1–12.
  • Simpson JHJ, Fraser JT, Greenwood IAJ. An optically pumped nuclear magnetic resonance gyroscope. IEEE Trans Aerosp. 1963;1:1107–1110.
  • Doherty MW, Manson NB, Delaney P, et al. The nitrogen-vacancy colour centre in diamond. Phys Rep. 2013 Jul;528:1–45.
  • Bayat K, Choy J, Baroughi MF, et al. Efficient, uniform, and large area microwave magnetic coupling to NV centers in diamond using double split-ring resonators. Nano Lett. 2014 Feb;14:1208–1213.
  • Popa I, Gaebel T, Neumann P, et al. Spin polarization in single spin experiments on defects in diamond. Isr J Chem. 2010;46. 4:393–398.
  • Jelezko F, Gaebel T, Popa I, et al. Observation of coherent oscillations in a single electron spin. Phys Rev Lett. 2004 Feb;92:076401.
  • Stanwix PL, Pham LM, Maze JR, et al. Coherence of nitrogen-vacancy electronic spin ensembles in diamond. Phys Rev B. 2010 Nov;82:201201.1–201201.4.
  • Kilin SY, Nizovtsev AP, Maevskaya TM, et al. Spectroscopy on single N-V defect centers in diamond: tunneling of nitrogen atoms into vacancies and fluorescence spectra. J Lumines. 2000 Apr;86:201–206.
  • Suter D, Álvarez GA. Colloquium: protecting quantum information against environmental noise. Rev Mod Phys. 2016 Oct;88:041001.
  • Degen CL, Reinhard F, Cappellaro P. Quantum sensing. Rev Mod Phys. 2017 Jul;89:035002.
  • Zhao N, Ho S-W, Liu R-B. Decoherence and dynamical decoupling control of nitrogen vacancy center electron spins in nuclear spin baths. Phys Rev B. 2012 Mar;85:115303.
  • Beha K, Fedder H, Wolfer M, et al. Diamond nanophotonics. Beilstein J Nanotechnol. 2012 Dec;3:895–908.
  • Jiang L, Hodges JS, Maze JR, et al. Repetitive readout of a single electronic spin via quantum logic with nuclear spin ancillae. Science. 2009 Oct;326:267–272.
  • Steiner M, Neumann P, Beck J, et al. Universal enhancement of the optical readout fidelity of single electron spins at nitrogen-vacancy centers in diamond. Phys Rev B. 2010 Jan;81:035205.
  • Jacques V, Neumann P, Beck J, et al. Dynamic polarization of single nuclear spins by optical pumping of nitrogen-vacancy color centers in diamond at room temperature. Phys Rev Lett. 2009 Feb;102:057403.
  • Broadway DA, Tetienne J-P, Stacey A, et al. Quantum probe hyperpolarisation of molecular nuclear spins. Nat Commun. 2018 Mar;9:1246.
  • Waddington DEJ, Sarracanie M, Zhang H, et al. Nanodiamond-enhanced mri via in situ hyperpolarization. Nat Commun. 2017 Apr;8:15118.
  • Ajoy A, Nazaryan R, Liu K, et al. Enhanced dynamic nuclear polarization via swept microwave frequency combs. Proc Nat Acad Sci. 2018 Oct;115:10576–10581.
  • Ajoy A, Liu K, Nazaryan R, et al. Orientation-independent room temperature optical 13 C hyperpolarization in powdered diamond. Sci Adv. 2018 May;4:eaar5492.
  • Schwartz I, Scheuer J, Tratzmiller B, et al. Robust optical polarization of nuclear spin baths using hamiltonian engineering of nitrogen-vacancy center quantum dynamics. Sci Adv. 2018 Aug;4:eaat8978.
  • Van DST, Wang ZH, Blok MS, et al. Decoherence-protected quantum gates for a hybrid solid-state spin register. Nature. 2012 Apr;484:82–86.
  • Neumann P, Beck J, Steiner M, et al. Single-shot readout of a single nuclear spin. Science. 2010 Jul;329:542–544.
  • Dréau A, Spinicelli P, Maze JR, et al. Single-shot readout of multiple nuclear spin qubits in diamond under ambient conditions. Phys Rev Lett. 2013 Feb;110:60502.
  • Ma Y, Hoang TM, Gong M, et al. Proposal for quantum many-body simulation and torsional matter-wave interferometry with a levitated nanodiamond. Phys Rev A. 2017 Aug;96:023827.
  • Geiselmann M, Juan ML, Renger J, et al. Three-dimensional optical manipulation of a single electron spin. Nature Nanotech. 2013 Feb;8:175–179.
  • Horowitz VR, Alemn BJ, Christle DJ, et al. Electron spin resonance of nitrogen-vacancy centers in optically trapped nanodiamonds. Proc Natl Acad Sci U S A. 2012 Aug;109:13493.
  • Hoang TM, Ahn J, Bang J, et al. Electron spin control of optically levitated nanodiamonds in vacuum. Nat Commun. 2016 Jul;7:12250.
  • Neukirch LP, von Haartman E, Rosenholm JM, et al. Multi-dimensional single-spin nano-optomechanics with a levitated nanodiamond. Nat Photonics. 2015 Sep;9:653–657.
  • Delord T, Nicolas L, Bodini M, et al. Diamonds levitating in a paul trap under vacuum: measurements of laser-induced heating via NV center thermometry. Appl Phys Lett. 2017 Jul;111:013101.
  • Pettit RM, Neukirch LP, Zhang Y, et al. Coherent control of a single nitrogen-vacancy center spin in optically levitated nanodiamond. J Opt Soc Am B. 2017 Jun;34:C31–C35.
  • Bennett SD, Kolkowitz S, Unterreithmeier QP, et al. Measuring mechanical motion with a single spin. New J Phys. 2012 Dec;14:125004.
  • Delord T, Nicolas L, Chassagneux Y, et al. Strong coupling between a single nitrogen-vacancy spin and the rotational mode of diamonds levitating in an ion trap. Phys Rev A. 2017 Dec;96:063810.
  • Kowarsky MA, Hollenberg LCL, Martin AM. Non-abelian geometric phase in the diamond nitrogen-vacancy center. Phys Rev A. 2014 Oct;90:042116.
  • Scala M, Kim MS, Morley GW, et al. Matter wave interferometry of a levitated thermal nano-oscillator induced and probed by a spin. Phys Rev Lett. 2013 Oct;111:180403.
  • Wan C, Scala M, Morley GW, et al. Free nano-object ramsey interferometry for large quantum superpositions. Phys Rev Lett. 2016 Sep;117:14.
  • Geraci A, Goldman H. Sensing short range forces with a nanosphere matter-wave interferometer. Phys Rev D. 2015 Sep;92:062002.
  • Schreiber KU, Klügel T, Wells JPR, et al. How to detect the chandler and the annual wobble of the earth with a large ring laser gyroscope. Phys Rev Lett. 2011;107:1–4.
  • Lai Y-H, Suh M-G, Lu Y-K, et al. Earth rotation measured by a chip-scale ring laser gyroscope. Nat Photonics. 2020;14:345–349.
  • Schreiber KU, Wells JPR. Invited review article: large ring lasers for rotation sensing. Rev Sci Instrum. 2013;84:4.
  • Li Y, Cao Y, He D, et al. Thermal phase noise in giant interferometric fiber optic gyroscopes. Opt Express. 2019;27:14121.
  • Müller T, Gilowski M, Zaiser M, et al. A compact dual atom interferometer gyroscope based on laser-cooled rubidium. Eur Phys J D. 2009;53:273–281.
  • Durfee DS, Shaham YK, Kasevich MA. Long-term stability of an area-reversible atom-interferometer sagnac gyroscope. Phys Rev Lett. 2006;97:1–4.
  • Fang JC, Qin J, Wan SA, et al. Atomic spin gyroscope based on 129Xe-Cs comagnetometer. Chinese Sci Bull. 2013;58:1512–1515.
  • Liu K, Zhang W, Chen W, et al. The development of micro-gyroscope technology. J Micromech Microeng. 2009;19:113001.
  • Wang L, Diao W, Song X, et al. Quantum gyroscope based on Berry phase of spins in diamond. 2018; (Feb 2018):88. doi:10.1117/12.2309334
  • Zhou X, Wu Y, Xiao D, et al. An investigation on the ring thickness distribution of disk resonator gyroscope with high mechanical sensitivity. Int J Mech Sci. 2016;117:174–181.
  • Bose S, Mazumdar A, Morley GW, et al. Spin entanglement witness for quantum gravity. Phys Rev Lett. 2017 Dec;119:240401.
  • Barnett SJ. Magnetization by rotation. Science. 1915;42:163–164.
  • Dreau A, Lesik M, Rondin L, et al. Avoiding power broadening in optically detected magnetic resonance of single NV defects for enhanced dc magnetic field sensitivity. Phys Rev B. 2011 Nov;84:195204.
  • Jensen K, Acosta VM, Jarmola A, et al. Light narrowing of magnetic resonances in ensembles of nitrogen-vacancy centers in diamond. Phys Rev B. 2013 Jan;87:014115.
  • Delord T, Nicolas L, Schwab L, et al. Electron spin resonance from NV centers in diamonds levitating in an ion trap. New J Phys. 2017 Mar;19:033031.
  • Delord T, Huillery P, Schwab L, et al. Ramsey interferences and spin echoes from electron spins inside a levitating macroscopic particle. Phys Rev Lett. 2018 Jul;121:053602.
  • Dobrovitski VV, Feiguin AE, Hanson R, et al. Decay of rabi oscillations by dipolar-coupled dynamical spin environments. Phys Rev Lett. 2009 Jun;102:237601.
  • Dobrovitski VV, Feiguin AE, Awschalom DD, et al. Decoherence dynamics of a single spin versus spin ensemble. Phys Rev B. 2008 Jun;77:245212.
  • Baibekov EI. Decay of rabi oscillations induced by magnetic dipole interactions in dilute paramagnetic solids. JETP Lett. 2011 May;93:292–297.
  • Boscaino R, Gelardi FM, Korb JP. Non-Bloch decay of transient nutations in S=1/2 systems: an experimental investigation. Phys Rev B. 1993 Sep;48:7077.
  • Jaskula J-C, Saha K, Ajoy A, et al. Cross-sensor feedback stabilization of an emulated quantum spin gyroscope. Phys Rev Appl. 2019 May;11:054010.
  • Romero-isart O, Pflanzer AC, Blaser F, et al. Large quantum superpositions and interference of massive nanometer-sized objects. Phys Rev Lett. 2011 Jul;107:1–4.
  • Butts DL. Development of a light force accelerometer. Massachusetts Institute of Technology; 2008.
  • Ahn J, Xu Z, Bang J, et al. Optically levitated nanodumbbell torsion balance and ghz nanomechanical rotor. Phys Rev Lett. 2018 Apr;121:33603.
  • Delić U, Reisenbauer M, Dare K, et al. Cooling of a levitated nanoparticle to the motional quantum ground state. Science. 2020 Jan;367:892–895.
  • Hobbs PCD. Ultrasensitive laser measurements without tears. Appl Optics. 1997 Feb;36:903–920.
  • Clevenson H, Trusheim ME, Teale C, et al. Broadband magnetometry and temperature sensing with a light trapping diamond wave guide. Nat Phys. 2015 Apr;11:393–397.
  • Frangeskou A, Rahman A, Rahman A, et al. Pure nanodiamonds for levitated optomechanics in vacuum. New J Phys. 2018 Apr;20:043016.
  • Hirose M, Cappellaro P. Coherent feedback control of a single qubit in diamond. Nature. 2016 Apr;532:77–80.

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