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核磁共振陀螺(NMRG)是基于量子原理的陀螺仪,具有高精度、体积小、抗干扰能力强等特点,是陀螺仪发展的重点方向之一。简要回顾了核磁共振陀螺的发展历史,介绍了20世纪有代表性的研究成果。叙述了核磁共振陀螺的基本工作原理和硬件系统构成。按照4种不同的技术路径:微型核磁共振陀螺、无自旋弛豫交换(SERF)核自旋陀螺、芯片级组合原子导航仪和基于金刚石氮空位的核磁共振陀螺,重点阐述近年来国外研究机构在核磁共振陀螺研究领域取得的最新成果,之后再介绍了近年来国内研究机构取得的主要研究成果。最后总结了核磁共振陀螺技术的最新发展趋势。
Abstract:The nuclear magnetic resonance gyroscope(NMRG)based on the quantum principle has features of high precision,compact size,strong anti-interference ability and so on,and is one of the most important development directions of gyroscopes.The development history of the NMRG is briefly reviewed,and the representative researches in the 20 th century are introduced.The basic operational principle and hardware system structure of the NMRG are described.The newest research achievements of the NMRG attained by foreign research institutes are mainly described according to four technical paths:micro-NMRG,spin exchange relaxation free(SERF)atomic spin gyroscope,chip-scale combinatorial atomic navigator(C-SCAN)and NMRG based on nitrogen-vacancy in diamond.The research achievements attained by domestic research institutes are also introduced.Finally,the development trend of the NMRG in the future is summarized.
[1]WOODMAN K F,FRANKS P W,RICHARDS M D.The nuclear magnetic resonance gyroscope:a review[J].Navigation,1987,40:366-384.
[2]DONLEY E A.Nuclear magnetic resonance gyroscopes[C]//Proceedings of 2010 IEEE Sensors Conference.Kona,HI,USA,2010:17-22.
[3]KANEGSBERG E.A nuclear magnetic resonance(NMR)gyro with optical magnetometer Detection[J].Proceedings of SPIE,1978,157:73-80.
[4]GROVER B C,KANEGSBERG E,MARK J G,et al.Nuclear magnetic resonance gyro:US,US4157495[P].1979-06-05.
[5]GREENWOOD I A.Nuclear gyroscope with unequal fields:US,US4147974 A[P].1979-04-03.
[6]SHAW G L.Modeling a cryogenic HE-3 nuclear gyro[D].California,USA:Stanford University,1981.
[7]KNAPPE S,SHAH V,SCHWINDT P D D,et al.Microfabricated atomic clock[J].Applied Physics Letters,2004,85(9):1460-1462.
[8]SCHWINDT P D D,KNAPPE S,SHAH V,et al.Chipscale atomic magnetometer[J].Applied Physics Letters,2006,85(26):6409-6411.
[9]MEYER D,LARSEN M.Nuclear magnetic resonance gyro for inertial navigation[J].Gyroscopy and Navigation,2014,5(2):75-82.
[10]LARSEN M,BULATOWICZ M.Nuclear magnetic resonance gyroscope:for DARPA's micro-technology for positioning,navigation and timing program[C]//Proceedings of IEEE International Frequency Control Symposium Proceedings.Baltimore,MD,USA,2012:1-5.
[11]WALKER T G,LARSEN M S.Chapter eight-spin-exchangepumped NMR gyros[J].Advances in Atomic,Molecular,and Optical Physics,2016,65:373-401.
[12]KORVER A,WYLLIE R,LANCOR B,et al.Suppression of spin-exchange relaxation using pulsed parametric resonance[J].Physical Review Letters,2013,111(4):043002-1-043002-5.
[13]KORVER A,THRASHER D,BULATOWICZ M,et al.Synchronous spin-exchange optical pumping[J].Physical Review Letters,2015,115(25):253001-1-253001-5.
[14]BULATOWICZ M D,LARSEN M S,GRIFFITH R.Nuclear magnetic resonance gyroscope mechanization:US,US8159220[P].2012.
[15]BULATOWICZ M D,GRIFFITH R C,LARSEN M S.Gyroscope system magnetic field error compensation:WO,WO2012099819 A1[P].2012-07-26.
[16]BULATOWICZ M D,LARSEN M S.Self-calibrating nuclear magnetic resonance(NMR)gyroscope system:EP,EP2952854[P].2015-12-09.
[17]EKLUND E J.Microgyroscope based on spin polarized nuclei[D].USA:University of California,Irvine,2008.
[18]GUNDETI V M.Folded MEMS approach to NMRG[D].USA:University of California,Irvine,2015.
[19]KORNACK T W,GHOSH R K,ROMALIS MV.Nuclear spin gyroscope based on an atomic comagnetometer[J].Physical Review Letters,2005,95(23):230801-1-230801-4.
[20]LIMES M,SHENG D,ROMAILS M.A3 He-129 Xe co-magnetometer with 87 Rb magnetometry[C]//Proceedings of APS Division of Atomic,Molecular and Optical Physics Meeting.Rhode Island,USA,2016.
[21]SHKEL A.The chip-scale combinatorial atomic navigator[J].GPS World,2013,24(8):8.
[22]KELLER J.AOSense to develop navigation chip that combines solid-state and atomic inertial sensors[EB/OL].(2013-4-11)[2017-02-08].http://www.militaryaerospace.com/articles/2013/04/AOSense-DARPA-CSCAN.html.
[23]LEDBETTER M P,JENSEN K,FISCHER R,et al.Gyroscopes based on nitrogen-vacancy centers in diamond[J].Physical Review:A,2012,86(5):052116-1-052116-5.
[24]AJOY A,CAPPELLARO P.Stable three-axis nuclear spin gyroscope in diamond[J].Physical Review:A,2012,86(6):062104-1-062104-7.
[25]le SAGE D,PHAM L M,BAR-GILL N,et al.Efficient photon detection from color centers in a diamond optical waveguide[J].Physical Review:B,2012,85(12):121202-1-121202-4.
[26]程向红,陈红梅,周雨青,等.核磁共振陀螺仪分析及发展方向[J].中国惯性技术学报,2006,14(6):86-90.
[27]FANG J C,QIN J.Advances in atomic gyroscopes:a view from inertial navigation applications[J].Sensors,2012,12(5):6331-6346.
[28]龚云鹏,高雁翎.导航级微型核磁共振陀螺仪技术综述[J].现代防御技术,2012,40(2):1-4.
[29]秦杰,汪世林,高溥泽,等.核磁共振陀螺技术研究进展[J].导航定位与授时,2014,1(2):64-69.
[30]严吉中,李攀,刘元正.原子陀螺基本概念及发展趋势分析[J].压电与声光,2015,37(5):810-817.
[31]FANG J C,QIN J,WAN S A,et al.Atomic spin gyroscope based on 129 Xe-Cs comagnetometer[J].Chinese Science Bulletin,2013,58(13):1512-1515.
[32]LI R,FAN W,JIANG L,et al.Rotation sensing using a KRb-21 Ne comagnetometer[J].Physical Review:A,2016,94(3):032109-1-032109-7.
[33]万双爱,孙晓光,郑辛,等.核磁共振陀螺技术发展展望[J].导航定位与授时,2017,4(1):7-13.
[34]王巍,王学锋,刘院省.一种基于宽谱激光泵浦的核磁共振陀螺仪:中国,CN104634339A[P].2015-05-20.
[35]易鑫,汪之国,夏涛,等.核磁共振陀螺中原子气室温度场的研究[J].中国光学,2016,9(6):671-677.
[36]李攀,刘元正,王继良.核磁共振陀螺多层磁屏蔽系统优化设计[J].中国惯性技术学报,2016,24(3):383-389.
[37]张鹏,陈海涛,孙帅,等.核磁共振陀螺仪敏感探测单元及该单元的制造方法:中国,CN104457729A[P].2015-03-25.
[38]浮建伟.基于金刚石氮-空位体系的量子陀螺仪的研究[D].合肥:中国科学技术大学,2014.
基本信息:
DOI:10.13250/j.cnki.wndz.2017.09.005
中图分类号:TN96
引用信息:
[1]程翔,刘华,王昢,等.核磁共振陀螺仪研究进展[J].微纳电子技术,2017,54(09):605-611.DOI:10.13250/j.cnki.wndz.2017.09.005.
基金信息:
国家自然科学基金面上项目(31271069);; 上海航天科技创新基金资助项目(SAST2016084)
2017-09-15
2017-09-15