[1] |
赵广立. 量子传感: “鼎新带动革故”[N]. 中国科学报, 2022. |
[2] |
徐婧, 唐川, 杨况骏瑜. 量子传感与测量领域国际发展态势分析[J]. 世界科技研究与发展, 2022, 44(01): 46-58. |
Xu Jing, Tang Chuan, Yang Kuangjunyu. Analysis on the international development strategies and trends of quantum sensing and measurement [J]. World Sci-Tech R & D, 2022, 44(1): 46-58. (in Chinese) |
[3] |
杨况骏瑜, 徐婧, 唐川. 趋势观察: 国际量子传感与测量领域战略部署与研究热点[J]. 中国科学院院刊, 2022, 37(02): 259-263. |
Yang Kuangjunyu, Xu Jing, Tang Chuan. Trend observation: strategic deployment and research hotspots in the field of international quantum sensing and measurement [J]. Bulletin of Chinese Academy of Sciences, 2022, 37(2): 259-263. (in Chinese) |
[4] |
Ashkin A. Acceleration and trapping of particles by radiation pressure [J]. Physical Review Letters, 1970, 24(4): 156-159. |
[5] |
Ashkin A, Dziedzic J M. Optical levitation by radiation pressure [J]. Applied Physics Letters, 1971, 19(8): 283-285. |
[6] |
Ashkin A, Dziedzic J. Optical levitation in high vacuum [J]. Applied Physics Letters, 1976, 28(6): 333-335. |
[7] |
Ashkin A, Dziedzic J M, Bjorkholm J E, et al. Observation of a single-beam gradient force optical trap for dielectric particles [J]. Optics Letters, 1986, 11(5): 288. |
[8] |
胡慧珠, 尹璋琦, 李楠, 等. 基于悬浮光力学的惯性传感颠覆性技术[J]. 中国工程科学, 2018, 20(06): 112-116. |
Hu Huizhu, Yin Zhangqi, Li Nan, et al. Inertial sensing disruptive technology based on levitated optomechanics [J]. Strategic Study of CAE, 2018, 20(6): 112-116. (in Chinese) |
[9] |
Chu S, Hollberg L, Bjorkholm J E, et al. Three-dimensional viscous confinement and cooling of atoms by resonance radiation pressure [J]. Physical Review Letters, 1985, 55(1): 48-51. |
[10] |
Lenef A, Rand S C. Electronic structure of the N-V center in diamond: Theory [J]. Physical Review B, 1996, 53(20): 13441. |
[11] |
Li R, Kong F, Zhao P, et al. Nanoscale electrometry based on a magnetic-field-resistant spin sensor [J]. Physical Review Letters, 2020, 124(24): 247701. |
[12] |
Moore D C, Geraci A A. Searching for new physics using optically levitated sensors [J]. Quantum Science Technology, 2021, 6(1): 014008. |
[13] |
Madsen L S, Waleed M, Casacio C A, et al. Ultrafast viscosity measurement with ballistic optical tweezers [J]. Nature Photonics, 2021, 15(5): 386-392. |
[14] |
Gieseler J, Gomez-solano J R, Magazzù A, et al. Optical tweezers-from calibration to applications: a tutorial [J]. Advances in Optics and Photonics, 2021, 13(1): 74-241. |
[15] |
Monteiro F, Afek G, Carney D, et al. Search for composite dark matter with optically levitated sensors [J]. Physical Review Letters, 2020, 125(18): 181102. |
[16] |
Chan J, Alegre T M, Safavi-naeini A H, et al. Laser cooling of a nanomechanical oscillator into its quantum ground state [J]. Nature, 2011, 478(7367): 89-92. |
[17] |
Kaltenbaek R, Hechenblaikner G, Kiesel N, et al. Macroscopic quantum resonators (MAQRO) testing quantum and gravitational physics with massive mechanical resonators [J]. Experimental Astronomy, 2012, 34: 123-164. |
[18] |
Li T, Kheifets S, Medellin D, et al. Measurement of the instantaneous velocity of a Brownian particle [J]. Science, 2010, 328(5986): 1673-1675. |
[19] |
Delić U, Reisenbauer M, Dare K, et al. Cooling of a levitated nanoparticle to the motional quantum ground state [J]. Science, 2020, 367(6480): 892-895. |
[20] |
李银妹, 姚焜. 光镊技术[M]. 北京: 科学出版社, 2015. |
[21] |
Millen J, Monteiro T S, Pettit R, et al. Optomechanics with levitated particles [J]. Reports on Progress in Physics, 2020, 83(2): 026401. |
[22] |
Gieseler J, Deutsch B, Quidant R, et al. Subkelvin parametric feedback cooling of a laser-trapped nanoparticle [J]. Physical Review Letters, 2012, 109(10): 103603. |
[23] |
Vovrosh J, Rashid M, Hempston D, et al. Parametric feedback cooling of levitated optomechanics in a parabolic mirror trap [J]. Journal of the Optical Society of America B: Optical Physics, 2017, 34(7): 1421-1428. |
[24] |
Chen X, Xiao G, Luo H, et al. Dynamics analysis of microsphere in a dual-beam fiber-optic trap with transverse offset [J]. Optics Express, 2016, 24(7): 7575-7584. |
[25] |
Li W, Li N, Shen Y, et al. Dynamic analysis and rotation experiment of an optical-trapped microsphere in air [J]. Applied Optics, 2018, 57(4): 823-828. |
[26] |
Xiao G, Yang K, Luo H, et al. Orbital rotation of trapped particle in a transversely misaligned dual-fiber optical trap [J]. IEEE Photonics Journal, 2016, 8(1): 1-8. |
[27] |
Zhu X, Li N, Yang J, et al. Revolution of a trapped particle in counter-propagating dual-beam optical tweezers under low pressure [J]. Optics Express, 2021, 29(7): 11169-11180. |
[28] |
祝训敏. 对射双光束真空光镊中大尺寸微球的运动探测和冷却[D]. 杭州: 浙江大学, 2021. |
Zhu Xunmin. Motion detection and cooling of a large-sized xicrosphere in dual-beam optical trap in vacuum[D]. Hangzhou: Zhejiang University, 2021. (in Chinese) |
[29] |
李文强. 非液体光阱系统中微球动力学研究[D]. 杭州: 浙江大学, 2020. |
Li Wenqiang. Research on dynamic analysis of trapped microsphere in non-liquid optical tweezers [D]. Hangzhou: Zhejiang University, 2020. (in Chinese) |
[30] |
Monteiro F, Ghosh S, Fine A G, et al. Optical levitation of 10-ng spheres with nano-g acceleration sensitivity [J]. Physical Review A, 2017, 96(6): 063841. |
[31] |
Moore D C, Rider A D, Gratta G. Search for millicharged particles using optically levitated microspheres [J]. Physical Review Letters, 2014, 113(25): 251801. |
[32] |
Ahn J, Xu Z, Bang J, et al. Ultrasensitive torque detection with an optically levitated nanorotor [J]. Nature Nanotechnology, 2020, 15(2): 89-93. |
[33] |
Millen J, Deesuwan T, Barker P, et al. Nanoscale temperature measurements using non-equilibrium Brownian dynamics of a levitated nanosphere [J]. Nature Nanotechnology, 2014, 9(6): 425-429. |
[34] |
Xiao G, Kuang T, Xiong W, et al. A PZT-assisted single particle loading method for dual-fiber optical trap in air [J]. Optics & Laser Technology, 2020, 126: 106115. |
[35] |
Blaser F, Kiesel N, Deli U, et al. Cavity cooling of an optically levitated submicron particle [J]. Proceedings of the National Academy of Sciences of the United States of America, 2013, 110(35): 14180-14185. |
[36] |
Li T. Fundamental Tests of Physics with Optically Trapped Microspheres[M]. Berlin: Springer Science & Business Media, 2012. |
[37] |
熊威, 邝腾芳, 曾炜卿, 等. 实用化光力加速度计中单微球重复起支技术[J]. 导航定位与授时, 2022, 9(02): 160-166. |
Xiong Wei, Kuang Tengfang, Zeng Weiqing, et al. A repeatable single particle loading technology in the practical light force accelerometer [J]. Navigation Positioning and Timing, 2022, 9(2): 160-166. (in Chinese) |
[38] |
Fu Z, She X, Li N, et al. Launch and capture of a single particle in a pulse-laser-assisted dual-beam fiber-optic trap [J]. Optics Communications, 2018, 417: 103-109. |
[39] |
田原, 郑瑜, 郭光灿, 等. 真空光镊技术与应用[J]. 物理实验, 2021, 41(01): 1-8+21. |
Tian Yuan, Zheng Yu, Guo Guangcan, et al. Technique and application of vacuum optical tweezers [J]. Physics Experimentation, 2021, 41(1): 1-8,21. (in Chinese) |
[40] |
胡慧珠, 傅振海, 葛晓佳, 等. 一种光悬浮式微球的起支方法及装置: 中国, CN105759074 B[P]. 2018-12-25. |
[41] |
Nieminen T A, Loke V L, Stilgoe A B, et al. Optical tweezers computational toolbox [J]. Journal of Optics A: Pure Applied Optics, 2007, 9(8): S196. |
[42] |
Callegari A, Mijalkov M, Gököz A B, et al. Computational toolbox for optical tweezers in geometrical optics [J]. Journal of the Optical Society of America B: Optical Physics, 2015, 32(5): 11-19. |
[43] |
Taylor M A, Waleed M, Stilgoe A B, et al. Enhanced optical trapping via structured scattering [J]. Nature Photonics, 2015, 9(10): 669-673. |
[44] |
Liu Y, Fan L, Lee Y E, et al. Optimal nanoparticle forces, torques, and illumination fields [J]. ACS Photonics, 2018, 6(2): 395-402. |
[45] |
Jiang Y, Zhu X, Yu W, et al. Propagation characteristics of the modified circular airy beam [J]. Optics Express, 2015, 23(23): 29834-29841. |
[46] |
Liu Z, Wang X, Hang K. Enhancement of trapping efficiency by utilizing a hollow sinh-Gaussian beam [J]. Scientific Reports, 2019, 9(1): 10187. |
[47] |
Kozawa Y, Sato S. Optical trapping of micrometer-sized dielectric particles by cylindrical vector beams [J]. Optics Express, 2010, 18(10): 10828-10833. |
[48] |
Shaltout A M, Shalaev V M, Brongersma M L. Spatiotemporal light control with active metasurfaces [J]. Science, 2019, 364(6441): 3100. |
[49] |
Ginis V, Tassin P, Soukoulis C M, et al. Enhancing optical gradient forces with metamaterials [J]. Physical Review Letters, 2013, 110(5): 057401. |
[50] |
Scullion M G, Arita Y, Krauss T F, et al. Enhancement of optical forces using slow light in a photonic crystal waveguide [J]. Optica, 2015, 2(9): 816-821. |
[51] |
Zhu B, Ren G, Gao Y, et al. Strong light confinement and gradient force in a hexagonal boron nitride slot waveguide [J]. Optics Letters, 2016, 41(21): 4991-4994. |
[52] |
Cao T, Bao J, Mao L. Switching of giant lateral force on sub-10 nm particle using phase-change nanoantenna [J]. Advanced Theory and Simulations, 2018, 1(2): 1700027. |
[53] |
Qian B, Montiel D, Bregulla A, et al. Harnessing thermal fluctuations for purposeful activities: the manipulation of single micro-swimmers by adaptive photon nudging [J]. Chemical Science, 2013, 4(4): 1420-1429. |
[54] |
Svoboda K, Block S M. Optical trapping of metallic Rayleigh particles [J]. Optics Letters, 1994, 19(13): 930-932. |
[55] |
Phillips D B, Padgett M J, Hanna S, et al. Shape-induced force fields in optical trapping [J]. Nature Photonics, 2014, 8(5): 400-405. |
[56] |
Shan X, Wang F, Wang D, et al. Optical tweezers beyond refractive index mismatch using highly doped upconversion nanoparticles [J]. Nature Nanotechnology, 2021, 16(5): 531-537. |
[57] |
Jannasch A, Demirörs A F, Van Oostrum P D, et al. Nanonewton optical force trap employing anti-reflection coated, high-refractive-index titania microspheres [J]. Nature Photonics, 2012, 6(7): 469-473. |
[58] |
Peng M, Luo H, Xiong W, et al. Enhanced optical trapping of ZrO2@TiO2 photonic force probe with broadened solvent compatibility [J]. Optics Express, 2022, 30(26): 46060-46069. |
[59] |
熊威. 基于双光束光阱的开环光力加速度传感理论与实验初步研究[D]. 长沙: 国防科技大学, 2019. |
Xiong Wei. Preliminary research on theory and experiment of the open-loop light force acceleration sensing based on the dual-beam optical trap[D]. Changsha: National University of Defense Technology, 2019. (in Chinese) |
[60] |
Gittes F, Schmidt C F. Interference model for back-focal-plane displacement detection in optical tweezers [J]. Optics Letters, 1998, 23(1): 7-9. |
[61] |
Volpe G, Kozyreff G, Petrov D. Backscattering position detection for photonic force microscopy [J]. Journal of Applied Physics, 2007, 102(8): 084701. |
[62] |
Taylor M A, Bowen W P. A computational tool to characterize particle tracking measurements in optical tweezers [J]. Journal of Optics, 2013, 15(8): 085701. |
[63] |
Ranjit G, Atherton D P, Stutz J H, et al. Attonewton force detection using microspheres in a dual-beam optical trap in high vacuum [J]. Physical Review A, 2015, 91(5): 051805. |
[64] |
Ranjit G, Cunningham M, Casey K, et al. Zeptonewton force sensing with nanospheres in an optical lattice [J]. Physical Review A, 2016, 93(5): 053801. |
[65] |
Xiong W, Xiao G, Han X, et al. Back-focal-plane displacement detection using side-scattered light in dual-beam fiber-optic traps [J]. Optics Express, 2017, 25(8): 9449-9457. |
[66] |
Zhu X, Li N, Yang J, et al. Displacement displacement detection decoupling in counter-propagating dual-beams optical tweezers with large-sized particle [J]. Sensors (Basel), 2020, 20(17): 4916. |
[67] |
王颖颖, 何沛彤, 梁韬, 等. 用于悬浮光力系统的低噪声四象限探测器研究[J]. 光学学报, 2023, 43(11): 1-14. |
Wang Yingying, He Peitong, Liang Tao, et al. A low-noise quadrant photodetector for levitated optomechanical systems [J]. Acta Optica Sinica, 2023, 43(11): 1104001. (in Chinese) |
[68] |
Li T C, Kheifets S, Raizen M G. Millikelvin cooling of an optically trapped microsphere in vacuum [J]. Nature Physics, 2011, 7(7): 527-530. |
[69] |
Rider A D, Blakemore C P, Gratta G, et al. Single-beam dielectric-microsphere trapping with optical heterodyne detection [J]. Physical Review A, 2018, 97(1): 013842. |
[70] |
Chen Z, Kuang T, Han X, et al. Differential displacement measurement of the levitated particle using D-shaped mirrors in the optical tweezers [J]. Optics Express, 2022, 30(17): 30791-30798. |
[71] |
Jensen-mcmullin C, Lee H P, Lyons E R. Demonstration of trapping, motion control, sensing and fluorescence detection of polystyrene beads in a multi-fiber optical trap [J]. Optics Express, 2005, 13(7): 2634-2642. |
[72] |
Chavez I, Huang R, Henderson K, et al. Development of a fast position-sensitive laser beam detector [J]. Review of Scientific Instruments, 2008, 79(10): 105104. |
[73] |
Ti C, Ho-thanh M T, Wen Q, et al. Objective-lens-free fiber-based position detection with nanometer resolution in a fiber optical trapping system [J]. Scientific Reports, 2017, 7(1): 13168. |
[74] |
Xiong W, Xiao G, Han X, et al. All-fiber interferometer for displacement and velocity measurement of a levitated particle in fiber-optic traps [J]. Applied Optics, 2019, 58(8): 2081-2084. |
[75] |
Hebestreit E, Frimmer M, Reimann R, et al. Calibration and energy measurement of optically levitated nanoparticle sensors [J]. Review of Scientific Instruments, 2018, 89(3): 033111. |
[76] |
Zheng Y, Zhou L M, Dong Y, et al. Robust optical-levitation-based metrology of nanoparticle's position and mass [J]. Physical Review Letters, 2020, 124(22): 223603. |
[77] |
王一松, 胡姝玲, 张雍丰. 惯导应用中光力加速度计前沿研究综述[J]. 激光与光电子学进展, 2022, 59(11): 123-135. |
Wang Yisong, Hu Shuling, Zhang Yongfeng. Review on frontier research of optical force accelerometer in inertial navigation application [J]. Laser & Optoelectronics Progress, 2022, 59(11): 1100008. (in Chinese) |
[78] |
Monteiro F, Li W, Afek G, et al. Force and acceleration sensing with optically levitated nanogram masses at microkelvin temperatures [J]. Physical Review A, 2020, 101(5): 053835. |
[79] |
Lewandowski C W, Knowles T D, Etienne Z B, et al. High-sensitivity accelerometry with a feedback-cooled magnetically levitated microsphere [J]. Physical Review Applied, 2021, 15(1): 014050. |
[80] |
Tebbenjohanns F, Frimmer M, Militaru A, et al. Cold damping of an optically levitated nanoparticle to microkelvin temperatures [J]. Physical Review Letters, 2019, 122(22): 223601. |
[81] |
Conangla G P, Ricci F, Cuairan M T, et al. Optimal feedback cooling of a charged levitated nanoparticle with adaptive control [J]. Physical Review Letters, 2019, 122(22): 223602. |
[82] |
Jain V, Gieseler J, Moritz C, et al. Direct measurement of photon recoil from a levitated nanoparticle [J]. Physical Review Letters, 2016, 116(24): 243601. |
[83] |
Jain V, Tebbenjohanns F, Novotny L. Microkelvin control of an optically levitated nanoparticle [C]//Frontiers in Optics 2016, OSA Technical Digest (online) (Optica Publishing Group, 2016), 2016: FF5B.2. |
[84] |
Vijayan J, Zhang Z, Piotrowski J, et al. Scalable all-optical cold damping of levitated nanoparticles [J]. Nature Nanotechnology, 2023, 18(1): 49-54. |
[85] |
Aspelmeyer M, Kippenberg T J, Marquardt F. Cavity optomechanics [J]. Reviews of Modern Physics, 2014, 86(4): 1391. |
[86] |
Piotrowski J, Windey D, Vijayan J, et al. Simultaneous ground-state cooling of two mechanical modes of a levitated nanoparticle [J]. Nature Physics, 2023, 6: 1-5. |
[87] |
Kalantarifard F, Elahi P, Makey G, et al. Intracavity optical trapping of microscopic particles in a ring-cavity fiber laser [J]. Nature Communications, 2019, 10(1): 2683. |
[88] |
Xiao G, Kuang T, Luo B, et al. Coupling between axial and radial motions of microscopic particle trapped in the intracavity optical tweezers [J]. Optics Express, 2019, 27(25): 36653-36661. |
[89] |
Kuang T, Xiong W, Luo B, et al. Optical confinement efficiency in the single beam intracavity optical tweezers [J]. Optics Express, 2020, 28(24): 35734-35747. |
[90] |
Kuang T, Liu Z, Xiong W, et al. Dual-beam intracavity optical tweezers with all-optical independent axial and radial self-feedback control schemes [J]. Optics Express, 2021, 29(19): 29936-29945. |
[91] |
Kuang T, Huang R, Xiong W, et al. Nonlinear multi-frequency phonon lasers with active levitated optomechanics [J]. Nature Physics, 2023: 1-6. |
[92] |
Arvanitaki A, Geraci A A. Detecting high-frequency gravitational waves with optically levitated sensors [J]. Physical Review Letters, 2013, 110(7): 071105. |
[93] |
Liang T, Zhu S, He P, et al. Yoctonewton force detection based on optically levitated oscillator [J]. Fundamental Research, 2022, 3(1): 57-62. |
[94] |
Hempston D, Vovrosh J, Toroš M, et al. Force sensing with an optically levitated charged nanoparticle [J]. Applied Physics Letters, 2017, 111(13): 133111. |
[95] |
刘骅锋, 焦世民, 涂良成. 国外光力学加速度计研究现状及发展趋势[J]. 导航与控制, 2021, 20(03): 1-8+43. |
Liu Huafeng, Jiao Shimin, Tu Liangcheng. Status and trend of optomechanical accelerometers abroad [J]. Navigation and Control, 2021, 20(3): 1-8, 43. (in Chinese) |
[96] |
Butts D L. Development of a light force accelerometer[D]. US: Massachusetts Institute of Technology, 2008. |
[97] |
Kotru K. Toward a demonstration of a light force accelerometer[D]. US: Massachusetts Institute of Technology, 2010. |
[98] |
Pu J, Zeng K, Wu Y, et al. Miniature optical force levitation system [J]. Chinese Optics Letters, 2022, 20(1): 013801. |
[99] |
Zeng K, Pu J, Wu Y, et al. Centrifugal motion of an optically levitated particle [J]. Optics Letters, 2021, 46(18): 4635-4638. |
[100] |
Pu J, Zeng K, Wu Y, et al. A miniature optical force dual-axis accelerometer based on laser diodes and small particles cavities [J]. Micromachines(Basel), 2021, 12(11): 1375. |
[101] |
Li C, Chou T-W. Mass detection using carbon nanotube-based nanomechanical resonators [J]. Applied Physics Letters, 2004, 84(25): 5246-5248. |
[102] |
Chaste J, Eichler A, Moser J, et al. A nanomechanical mass sensor with yoctogram resolution [J]. Nature Nanotechnology, 2012, 7(5): 301-304. |
[103] |
Blakemore C P, Rider A D, Roy S, et al. Precision mass and density measurement of individual optically levitated microspheres [J]. Physical Review Applied, 2019, 12(2): 024037. |
[104] |
Ricci F, Cuairan M T, Conangla G P, et al. Accurate mass measurement of a levitated nanomechanical resonator for precision force-sensing [J]. Nano Letters, 2019, 19(10): 6711-6715. |
[105] |
Zheng Y, Guo G, Sun F. Cooling of a levitated nanoparticle with digital parametric feedback [J]. Applied Physics Letters, 2019, 115(10): 101105. |
[106] |
Zhu S, Fu Z, Gao X, et al. Nanoscale electric field sensing using a levitated nano-resonator with net charge [J]. Photonics Research, 2023, 11(2): 279-289. |
[107] |
Beth R A. Mechanical detection and measurement of the angular momentum of light [J]. Physical Review, 1936, 50(2): 115. |
[108] |
Simpson N B, Dholakia K, Allen L, et al. Mechanical equivalence of spin and orbital angular momentum of light: an optical spanner [J]. Optics Letters, 1997, 22(1): 52-54. |
[109] |
Padgett M, Allen L. The angular momentum of light: optical spanners and the rotational frequency shift [J]. Optical and Quantum Electronics, 1999, 31: 1-12. |
[110] |
韩翔, 陈鑫麟, 熊威, 等. 真空光镊系统及其在精密测量中的研究进展[J]. 中国激光, 2021, 48(04): 187-206. |
Han Xiang, Chen Xinlin, Xiong Wei, et al. Vaccum optical tweezers system and its research progress in precision measurement [J]. Chinese Journal of Lasers, 2021, 48(4): 0401011. (in Chinese) |
[111] |
Arita Y, Mazilu M, Dholakia K. Laser-induced rotation and cooling of a trapped microgyroscope in vacuum [J]. Nature Communications, 2013, 4(1): 2374. |
[112] |
Reimann R, Doderer M, Hebestreit E, et al. GHz rotation of an optically trapped nanoparticle in vacuum [J]. Physical Review Letters, 2018, 121(3): 033602. |
[113] |
Jin Y, Yan J, Rahman S J, et al. 6 GHz hyperfast rotation of an optically levitated nanoparticle in vacuum [J]. Photonics Research, 2021, 9(7): 1344-1350. |
[114] |
Hoang T M, Ma Y, Ahn J, et al. Torsional optomechanics of a levitated nonspherical nanoparticle [J]. Physical Review Letters, 2016, 117(12): 123604. |
[115] |
Ahn J, Xu Z, Bang J, et al. Optically levitated nanodumbbell torsion balance and GHz nanomechanical rotor [J]. Physical Review Letters, 2018, 121(3): 033603. |