Measuring Transverse Relaxation Time of Xenon Atoms Based on Single Beam of Laser in Nuclear Magnetic Resonance Gyroscope

Nuclear magnetic resonance gyroscope (NMRG) has the characteristics of high precision and miniaturization, and is one of the main applications of quantum technology in the field of navigation. The transverse relaxation time ( T 2 ) of the xenon nuclear spin in the atomic cell of the NMRG directly af...

Full description

Saved in:
Bibliographic Details
Published inShanghai jiao tong da xue xue bao Vol. 28; no. 5; pp. 569 - 576
Main Authors Zhong, Guochen, Liu, Hua, Guo, Yang, Li, Shaoliang, Zhao, Wanliang, Cheng, Yuxiang
Format Journal Article
LanguageEnglish
Published Shanghai Shanghai Jiaotong University Press 01.10.2023
Springer Nature B.V
Subjects
Architecture
Cesium
Circular polarization
Computer Science
Electrical Engineering
Engineering
Gyroscopes
Larmor precession
Lasers
Life Sciences
Magnetic fields
Magnetic moments
Materials Science
NMR
Nuclear magnetic resonance
Nuclear spin
Precession
Random walk
Relaxation time
Temperature effects
Xenon
nuclear magnetic resonance gyroscope (NMRG)
A
TN 219
magnetometer
transverse relaxation time
磁强计
free-induction decay
自由感应衰减
核磁共振陀螺仪
横向弛豫时间
nuclear magnetic resonance gyroscope(NMRG)
freee-induction decay
Online AccessGet full text

Cover

More Information
Summary:Nuclear magnetic resonance gyroscope (NMRG) has the characteristics of high precision and miniaturization, and is one of the main applications of quantum technology in the field of navigation. The transverse relaxation time ( T 2 ) of the xenon nuclear spin in the atomic cell of the NMRG directly affects the angular random walk of the gyro. Accurate and rapid measurement of T 2 is conducive to further improvement of gyroscope. At present, for the measurement of T 2 , the schemes of two orthogonal lasers for pumping and detecting are usually used. By applying two fast-switching orthogonal static magnetic fields and a single beam of circularly polarized laser with corresponding wavelength to pump the atomic cell, the xenon nuclear macroscopic magnetic moment Larmor precession is generated. The cesium atoms parametric magnetometer in cell is formed to detect the free induction decay signal generated by nuclear spin precession of xenon atoms. The measurement of T 2 by a single laser simplifies the measurement equipment compared with traditional method with two lasers. The experimental results show that the T 2 of xenon atoms is more than 10 s, and the effects of temperature are studied, which lay the foundation for the subsequent improvement of gyro performance.
ISSN:1007-1172
1995-8188
DOI:10.1007/s12204-022-2436-3