Sun et al., 2017 - Google Patents

All-optical vector cesium magnetometer

Sun et al., 2017

Document ID: 16883138676751539592
Author: Sun W; Huang Q; Huang Z; Wang P; Zhang J
Publication year: 2017
Publication venue: Chinese Physics Letters

External Links

Cited by

Snippet

Based on power modulation of a pump laser and precessional projection detection, we present an all-optical vector magnetometer of cesium, which has a demonstrated magnitude sensitivity of 80 fT/Hz 1/2 and an orientation sensitivity of 0.1/Hz 1/2. In the device, four main …

Continue reading at cpl.iphy.ac.cn (PDF) (other versions)

TVFDJXOCXUVLDH-UHFFFAOYSA-N Cesium data:image/svg+xml;base64,PD94bWwgdmVyc2lvbj0nMS4wJyBlbmNvZGluZz0naXNvLTg4NTktMSc/Pgo8c3ZnIHZlcnNpb249JzEuMScgYmFzZVByb2ZpbGU9J2Z1bGwnCiAgICAgICAgICAgICAgeG1sbnM9J2h0dHA6Ly93d3cudzMub3JnLzIwMDAvc3ZnJwogICAgICAgICAgICAgICAgICAgICAgeG1sbnM6cmRraXQ9J2h0dHA6Ly93d3cucmRraXQub3JnL3htbCcKICAgICAgICAgICAgICAgICAgICAgIHhtbG5zOnhsaW5rPSdodHRwOi8vd3d3LnczLm9yZy8xOTk5L3hsaW5rJwogICAgICAgICAgICAgICAgICB4bWw6c3BhY2U9J3ByZXNlcnZlJwp3aWR0aD0nMzAwcHgnIGhlaWdodD0nMzAwcHgnIHZpZXdCb3g9JzAgMCAzMDAgMzAwJz4KPCEtLSBFTkQgT0YgSEVBREVSIC0tPgo8cmVjdCBzdHlsZT0nb3BhY2l0eToxLjA7ZmlsbDojRkZGRkZGO3N0cm9rZTpub25lJyB3aWR0aD0nMzAwLjAnIGhlaWdodD0nMzAwLjAnIHg9JzAuMCcgeT0nMC4wJz4gPC9yZWN0Pgo8dGV4dCB4PScxMzguMCcgeT0nMTcwLjAnIGNsYXNzPSdhdG9tLTAnIHN0eWxlPSdmb250LXNpemU6NDBweDtmb250LXN0eWxlOm5vcm1hbDtmb250LXdlaWdodDpub3JtYWw7ZmlsbC1vcGFjaXR5OjE7c3Ryb2tlOm5vbmU7Zm9udC1mYW1pbHk6c2Fucy1zZXJpZjt0ZXh0LWFuY2hvcjpzdGFydDtmaWxsOiMzQjQxNDMnID5DPC90ZXh0Pgo8dGV4dCB4PScxNjUuNicgeT0nMTcwLjAnIGNsYXNzPSdhdG9tLTAnIHN0eWxlPSdmb250LXNpemU6NDBweDtmb250LXN0eWxlOm5vcm1hbDtmb250LXdlaWdodDpub3JtYWw7ZmlsbC1vcGFjaXR5OjE7c3Ryb2tlOm5vbmU7Zm9udC1mYW1pbHk6c2Fucy1zZXJpZjt0ZXh0LWFuY2hvcjpzdGFydDtmaWxsOiMzQjQxNDMnID5zPC90ZXh0Pgo8cGF0aCBkPSdNIDE4Ni43LDE1MC4wIEwgMTg2LjcsMTQ5LjggTCAxODYuNywxNDkuNyBMIDE4Ni43LDE0OS41IEwgMTg2LjYsMTQ5LjMgTCAxODYuNiwxNDkuMiBMIDE4Ni41LDE0OS4wIEwgMTg2LjQsMTQ4LjkgTCAxODYuMywxNDguNyBMIDE4Ni4yLDE0OC42IEwgMTg2LjAsMTQ4LjUgTCAxODUuOSwxNDguNCBMIDE4NS44LDE0OC4zIEwgMTg1LjYsMTQ4LjIgTCAxODUuNSwxNDguMSBMIDE4NS4zLDE0OC4xIEwgMTg1LjEsMTQ4LjAgTCAxODUuMCwxNDguMCBMIDE4NC44LDE0OC4wIEwgMTg0LjYsMTQ4LjAgTCAxODQuNCwxNDguMCBMIDE4NC4zLDE0OC4xIEwgMTg0LjEsMTQ4LjEgTCAxODQuMCwxNDguMiBMIDE4My44LDE0OC4yIEwgMTgzLjYsMTQ4LjMgTCAxODMuNSwxNDguNCBMIDE4My40LDE0OC41IEwgMTgzLjMsMTQ4LjcgTCAxODMuMSwxNDguOCBMIDE4My4xLDE0OC45IEwgMTgzLjAsMTQ5LjEgTCAxODIuOSwxNDkuMiBMIDE4Mi44LDE0OS40IEwgMTgyLjgsMTQ5LjYgTCAxODIuOCwxNDkuNyBMIDE4Mi43LDE0OS45IEwgMTgyLjcsMTUwLjEgTCAxODIuOCwxNTAuMyBMIDE4Mi44LDE1MC40IEwgMTgyLjgsMTUwLjYgTCAxODIuOSwxNTAuOCBMIDE4My4wLDE1MC45IEwgMTgzLjEsMTUxLjEgTCAxODMuMSwxNTEuMiBMIDE4My4zLDE1MS4zIEwgMTgzLjQsMTUxLjUgTCAxODMuNSwxNTEuNiBMIDE4My42LDE1MS43IEwgMTgzLjgsMTUxLjggTCAxODQuMCwxNTEuOCBMIDE4NC4xLDE1MS45IEwgMTg0LjMsMTUxLjkgTCAxODQuNCwxNTIuMCBMIDE4NC42LDE1Mi4wIEwgMTg0LjgsMTUyLjAgTCAxODUuMCwxNTIuMCBMIDE4NS4xLDE1Mi4wIEwgMTg1LjMsMTUxLjkgTCAxODUuNSwxNTEuOSBMIDE4NS42LDE1MS44IEwgMTg1LjgsMTUxLjcgTCAxODUuOSwxNTEuNiBMIDE4Ni4wLDE1MS41IEwgMTg2LjIsMTUxLjQgTCAxODYuMywxNTEuMyBMIDE4Ni40LDE1MS4xIEwgMTg2LjUsMTUxLjAgTCAxODYuNiwxNTAuOCBMIDE4Ni42LDE1MC43IEwgMTg2LjcsMTUwLjUgTCAxODYuNywxNTAuMyBMIDE4Ni43LDE1MC4yIEwgMTg2LjcsMTUwLjAgTCAxODQuNywxNTAuMCBaJyBzdHlsZT0nZmlsbDojMDAwMDAwO2ZpbGwtcnVsZTpldmVub2RkO2ZpbGwtb3BhY2l0eToxO3N0cm9rZTojMDAwMDAwO3N0cm9rZS13aWR0aDowLjBweDtzdHJva2UtbGluZWNhcDpidXR0O3N0cm9rZS1saW5lam9pbjptaXRlcjtzdHJva2Utb3BhY2l0eToxOycgLz4KPC9zdmc+Cg== data:image/svg+xml;base64,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 [Cs] 0 title abstract description 8

Classifications

- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R33/00—Arrangements or instruments for measuring magnetic variables
- G01R33/20—Arrangements or instruments for measuring magnetic variables involving magnetic resonance
- G01R33/24—Arrangements or instruments for measuring magnetic variables involving magnetic resonance for measuring direction or magnitude of magnetic fields or magnetic flux
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R33/00—Arrangements or instruments for measuring magnetic variables
- G01R33/20—Arrangements or instruments for measuring magnetic variables involving magnetic resonance
- G01R33/44—Arrangements or instruments for measuring magnetic variables involving magnetic resonance using nuclear magnetic resonance [NMR]
- G01R33/46—NMR spectroscopy
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R33/00—Arrangements or instruments for measuring magnetic variables
- G01R33/20—Arrangements or instruments for measuring magnetic variables involving magnetic resonance
- G01R33/28—Details of apparatus provided for in groups G01R33/44 - G01R33/64
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R33/00—Arrangements or instruments for measuring magnetic variables
- G01R33/02—Measuring direction or magnitude of magnetic fields or magnetic flux
- G01R33/035—Measuring direction or magnitude of magnetic fields or magnetic flux using superconductive devices
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N24/00—Investigating or analyzing materials by the use of nuclear magnetic resonance, electron paramagnetic resonance or other spin effects
- G01N24/08—Investigating or analyzing materials by the use of nuclear magnetic resonance, electron paramagnetic resonance or other spin effects by using nuclear magnetic resonance
- G—PHYSICS
- G01—MEASURING; TESTING
- G01V—GEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS
- G01V7/00—Measuring gravitational fields or waves; Gravimetric prospecting or detecting
- G01V7/005—Measuring gravitational fields or waves; Gravimetric prospecting or detecting using a resonating body or device, e.g. string
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R13/00—Arrangements for displaying electric variables or waveforms

Similar Documents

Publication	Publication Date	Title
Zentile et al.	2014	The hyperfine Paschen–Back Faraday effect
Savukov et al.	2017	High-sensitivity operation of single-beam optically pumped magnetometer in a kHz frequency range
Sun et al.	2017	All-optical vector cesium magnetometer
Karaulanov et al.	2016	Spin-exchange relaxation-free magnetometer with nearly parallel pump and probe beams
Hu et al.	2017	Reduction of far off-resonance laser frequency drifts based on the second harmonic of electro-optic modulator detection in the optically pumped magnetometer
Fang et al.	2016	Low frequency magnetic field suppression in an atomic spin co-magnetometer with a large electron magnetic field
Fan et al.	2017	A three-axis atomic magnetometer for temperature-dependence measurements of fields in a magnetically shielded environment
Xiao et al.	2021	Single-beam three-axis optically pumped magnetometers with sub-100 femtotesla sensitivity
Jiang et al.	2022	A single-beam dual-axis atomic spin comagnetometer for rotation sensing
Lenci et al.	2012	A magnetometer suitable for measurement of the Earth's field based on transient atomic response
Li et al.	2017	A dual-axis, high-sensitivity atomic magnetometer
Yang et al.	2019	High bandwidth three-axis magnetometer based on optically polarized 85Rb under unshielded environment
Fang et al.	2016	Dynamics of Rb and 21Ne spin ensembles interacting by spin exchange with a high Rb magnetic field
Fu et al.	2015	Spin dynamics of the potassium magnetometer in spin-exchange relaxation free regime
Fan et al.	2019	Low drift nuclear spin gyroscope with probe light intensity error suppression
Quan et al.	2015	Simultaneous measurement of magnetic field and inertia based on hybrid optical pumping
Li et al.	2022	Single-beam triaxial spin-exchange relaxation-free atomic magnetometer utilizing transverse modulation fields
Zhang et al.	2017	Parameter analysis for a nuclear magnetic resonance gyroscope based on 133Cs–129Xe/131Xe
Ma et al.	2022	Accurate determination of alkali atom density based on zero-field magnetic resonance in a single-beam spin-exchange relaxation-free atomic magnetometer
Zhao et al.	2022	Ultra-sensitive all-optical comagnetometer with laser heating
Fang et al.	2015	In-situ measurement of magnetic field gradient in a magnetic shield by a spin-exchange relaxation-free magnetometer
Xing et al.	2020	Optical rotation detection method based on acousto-optic modulation in an atomic spin co-magnetometer
Marmugi et al.	2015	Magnetic induction imaging with optical atomic magnetometers: towards applications to screening and surveillance
Wang et al.	2016	Study of the optimal duty cycle and pumping rate for square-wave amplitude-modulated Bell–Bloom magnetometers
Hu et al.	2017	An atomic spin precession detection method based on electro-optic modulation in an all-optical K–Rb hybrid atomic magnetometer