RU2744814C1 - Fluctuation optical magnetometer - Google Patents

Abstract

FIELD: magnetometry.

SUBSTANCE: essence of the invention lies in the fact that the device for recording a magnetic field contains a polarizing element made linear, between the polarizing element and the cell with atomic magnetic dipoles on one optical axis is a focusing lens, between the cell and the photodetector made in the form of a balanced photodiode, there is a polarization divider and a refocusing lens, and a radio frequency spectrum analyzer with digital mathematical processing is used as a measuring device.

EFFECT: technical result is increase in accuracy and information content of measuring the magnetic field, and decrease in the size of the device.

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Description

The invention relates to the field of magnetometry, in particular to magnetic field sensors, namely to optical magnetometers based on cells with atomic pairs, designed to measure constant or slowly changing magnetic fields, and can be used to solve a wide range of fundamental and applied problems of geophysics, geology , archeology, military affairs, magneto-optics, seismological service, in systems of remote detection of magnetic objects.

Known quantum magnetometers [1], which use the principle of optical pumping and registration of resonance in transitions from the ground state of cesium vapor. These magnetometers use circularly polarized light for optical pumping of cesium vapor; the signal is recorded by measuring the modulation frequency of the resonant absorption of light. Magnetometers of this type are characterized by a dependence of the measurement results on the pump power, an error in determining the frequency due to the failure of the precession phase, and a decrease in accuracy in inhomogeneous magnetic fields due to the large volume of the signal-generating region, which is the entire region of the light beam within the cell. The device is technically complex, since the design requires the use of a pumping radiation spectral filter and an electrical circuit with a radio frequency coil and a feedback loop.

Known is a quantum magnetometer with optical pumping [2], which has a phase memory cell in the feedback loop to eliminate phase adjustment errors. The frequency measurement is performed with alternating periods of spontaneous and induced precession, which introduces an unrecoverable error in determining the frequency.

Known quantum magnetometer [3], in which optical pumping is carried out using a monochromatic solid-state laser. However, laser sources in magnetometers of this type require precise tuning in the wavelength of the transition from the ground to the excited state of the cell. The use of a solid-state laser for this purpose significantly increases the cost of the design of the magnetometer.

Known quantum magnetometer with optical pumping [4], which is the closest in technical solution of the problem to the proposed invention and selected as a prototype.

The known device includes a diode laser that emits a pumping laser beam with resonant optical radiation, a cell with atomic vapors, which is placed in an external magnetic field, and a means for registering a magnetic field, consisting of a photodiode that converts the secondary radiation of the cell atoms into a photocurrent, and a measuring device that records the magnitude of the magnetic field from the modulation frequency of the photocurrent.

The disadvantages of the prototype are insufficient information content when measuring the field due to the measurement of one precession frequency, reduced accuracy in inhomogeneous magnetic fields due to the large volume of the region that generates the signal (the entire region of the light beam within the cell) and the accompanying increase in the uncertainty of the precession frequency of atoms in the beam, high cost of the structure due to the use of a source of monochromatic radiation, which requires precise spectral tuning to enter the optical resonance of the cell, a radio frequency coil with a feedback loop, and a frequency generator, the error in magnetic field measurements due to the dependence of the position of the central frequency of atomic precession on the pump power and inaccuracy in measuring the phase of the induced signal.

The claimed invention is free from the above disadvantages of the prototype and its technical result consists in increasing the information content and accuracy of measurements due to the registration of the full radio frequency spectrum of the signal, the implementation of a one-time measurement of the angle between the magnetic field and the axis of light propagation, sharp focusing of light in the cell and monitoring the uniformity of the magnetic field along the shape of the obtained spectra, simplification and cheapening of the design, and a decrease in the measurement error due to the registration of the frequency of spontaneous precession of atoms.

The essence of the claimed invention is illustrated in FIG. 1 to FIG. 6.

FIG. 1 shows a diagram of the claimed device.

FIG. 2 shows the result of measurements of several, mostly transverse to the optical axis, magnetic fields obtained during the implementation of the device according to item 1 (Example 1).

FIG. 3 shows the result of measuring several magnetic fields, which are predominantly transverse to the optical axis, with a small step of change, obtained during the implementation of the device according to paragraph 1 (Example 1).

FIG. 4 shows the result of measuring the magnetic field inclined with respect to the optical axis, obtained when implementing the device according to paragraph 1 (Example 1).

FIG. 5 shows the result of measurements of several, mostly transverse to the optical axis, magnetic fields obtained during the implementation of the device according to item 2 (Example 2).

FIG. 6 shows the result of measurements of several, mostly transverse to the optical axis, magnetic fields obtained during the implementation of the device according to item 1 (Example 3).

The diagram of the claimed invention is illustrated in FIG. 1, on which a monochromatic light source 1 emits a beam of light, which passes into a detection circuit located in an external arbitrary magnetic field and through lens 2 and a linear polarizer 3 is focused on a cell 4 with alkali metal vapors, then it is split by a polarizing beam splitter 5 into two orthogonal linearly polarized components and through the refocusing lens 6 enters the input of the balanced photodetector 7, which converts the luminous flux into a differential photocurrent. The photocurrent enters the input of the measuring device 8, which analyzes the radio frequency spectrum and digital data processing.

The circuit of the claimed invention according to paragraph 2 is characterized in that when using a diode laser with an internal resonator, the installation of a linear polarizing element is not required.

The work of the claimed invention is based on the principle of spin noise spectroscopy, first presented by V.S. Zapassky and E.B. Aleksandrov in 1981 [5] and is carried out as follows. As shown in FIG. 1, a monochromatic laser beam from a source 1 acquires linear polarization on a linear polarizing element 2 and is focused by a lens 3 on a cell with atomic vapors 4. The beam has a wavelength close to the resonant frequency of the transition from the ground to an excited state of atomic vapors used in cell 4, however having some positive or negative detuning. The value of the permissible detuning is determined by the spectral region in which the Faraday rotation of the system of atomic vapors is sufficiently large and their absorption is rather low. The specific detuning values thus depend on the atomic gas used and the cell configuration; however, in the overwhelming majority of cases, the permissible detuning is an order of magnitude larger than the optical transition width. When a cell is placed in a magnetic field, random fluctuations of the magnetic field of atoms undergo constant precession around the direction of the external magnetic field at the Larmor frequency, which is determined by the gyromagnetic ratio for a given substance. In well-known optically pumped quantum magnetometers [1-4], this fluctuation is a seed for the onset of self-oscillations of the system, the amplitude of which is large enough for registration. In the proposed device, the laser beam passes in the region of transparency of the medium and undergoes inelastic scattering by atoms freely precessing in a magnetic field. The difference in the frequencies of the scattered and original waves is equal to the Larmor frequency. Their interference leads to a weak modulation of the azimuth of the plane of polarization of the light transmitted through the cell. The light thus modulated passes through the polarization divider 5, the axes of which are oriented at 45 ° to the azimuth of the plane of polarization of the source light. Orthogonally polarized fluxes through the refocusing lens 6 are directed to two arms of the balanced photodiode 7, the output of which receives a signal for subtracting the photocurrents of the photodiodes. As a result of the subtraction of the photocurrents, the excess (intensity) fluctuations of the light flux are suppressed, and the polarization ones are doubled. The differential photocurrent from the photodetector output is fed to the input of the measuring device 8, which is an analyzer of the radio frequency spectrum of the signal and a digital data processing system. Systems of this type are known and can be implemented, for example, as a digital instrument equipped with a fast ADC and performing a fast Fourier transform in hardware, and a PC for data processing. The spontaneous spin precession signal is thus detected in the radio frequency spectrum of the photocurrent power density. The spectral peak at the Larmor frequency determines the total magnitude of the magnetic field applied to the cell. The angle α between the direction of the magnetic field applied to the cell and the optical axis is determined from the relation

where A and B are the areas of the peaks at the Larmor frequency and zero frequency, respectively, in the signal power density spectrum.

The specified technical result of the claimed invention is achieved as follows. The object of registration, in contrast to the prototype and analogs, is not the one induced by the radio frequency coil, but the free and spontaneous precession of atoms in an external magnetic field, as a result of which the increase in frequency stability results from the free (and not forced, as in known analogs) nature of spin oscillations , and an increase in the measurement accuracy is achieved by analyzing the full radio-frequency spectrum of the accumulated signal instead of recording at a dedicated frequency. Amplification of the signal occurs due to sharp focusing on the cell, since the relative noise signal, in contrast to the regular one, is inversely proportional to the cross-sectional area of the beam, and is created by the region limited by the Rayleigh length and the waist section of the light beam; and also due to the use of a balanced circuit that suppresses excess noise and doubles the polarization signal. Reducing the area of space that generates a signal also leads to an increase in accuracy in inhomogeneous fields. Increasing the information content of measurements consists in the possibility of measuring the angle between the optical axis and the direction of the magnetic field and is achieved as a result of determining the ratio between the signal amplitudes at zero and Larmor frequencies, in this way depending on the magnitude of the magnetic field projections on the optical axis and the plane perpendicular to it. In addition, the increase in information content lies in the possibility of tracking the inhomogeneity of the field, which leads to broadening and distortion of the shape of the peaks in the signal spectra. Simplification of the design is achieved as a result of the use of a spectrum analyzer as a recording device instead of an autogeneration circuit with a feedback loop, a phase shifter and a frequency counter, as well as the use of a laser diode with an internal resonator.

The technical result has been tested in real conditions of the St. Petersburg State University and below are the results of testing.

Example 1.

The approbation of Example 1 is illustrated in FIG. 1-4. In the diagram of FIG. 1, a Sacher Lasertechnik Lynx laser was used as a source of laser radiation 1, spectrally tuned near the absorption line D2 of cesium (the radiation wavelength was 852.1 ± 0.05 nm), the radiation of which through lens 2 and the polarizer is focused on the cell 4. Polarizer 3 is not required in this case , since the laser radiation is linearly polarized. A spherical cell 4 containing cesium and filled with a buffer gas xenon at a pressure of 3 Torr is heated to an operating temperature of 100 ± 2 ° C. The light passes through the polarizing divider 5, being divided into two orthogonally polarized components, which are directed through the lens 6 to the Thorlabs PDB460A balanced photodetector 7, the differential photocurrent from which enters the measuring device 8, which consists of a Tektronix RSA5103A spectrum analyzer and a personal computer. The change in the magnetic field in the cell was created by a permanent magnet. FIG. 2 shows the results of measurements of several predominantly transverse fields generated by a permanent neodymium magnet. FIG. 3 shows several measurements of the transverse magnetic field and indicates the achieved measurement accuracy. FIG. 4 shows the measurement of some arbitrary oriented constant magnetic field, the magnitude and angle between the magnetic field and the axis of light propagation are determined.

Example 2.

The approbation of Example 2 is illustrated in FIG. 1 and 5. The installation corresponding to the diagram of FIG. 1, differs in that an analog spectrum analyzer with a frequency band of 2.7-8.3 MHz with a DAC connected to a PC for data processing was used as a measuring device. FIG. 5 shows the results of measurements of several predominantly transverse fields generated by a permanent neodymium magnet.

Example 3.

The approbation of Example 3 is illustrated in FIG. 1 and 6. The installation corresponding to the diagram of FIG. 1, differs in that a laser diode with an internal resonator, tuned near the absorption line of cesium Thorlabs L852P50, is used as a source of laser radiation 1. The diode was adjusted to the working area by changing the magnitude of the diode supply current. The measurement results of several arbitrary transverse fields are shown in FIG. 6.

The technical and economic efficiency of the claimed invention, as shown by the above examples of approbation, consists in the fact that an optical magnetometer is proposed with an accuracy and information content that is increased in comparison with the prototype. The proposed design is simplified in comparison with the prototype, the requirements for the spectral position of the radiation source are reduced, which will lead to a decrease in the cost of manufacturing instruments for measuring laboratory and terrestrial magnetic fields. The device makes it possible to carry out more informative measurements of the magnetic field, namely, to measure the angle between the optical axis and the direction of the external magnetic field, as well as to monitor the inhomogeneity of the measured field along the width and shape of peaks in the signal spectra.

List of used literature

1. William E. Bell, Arnold L. Bloom // Optical Magnetometers // US Patent US 3,257,608 02.02.1961.

2. E.H. Pestov // Quantum magnetometer // USSR Patent 404035 G 01v 3/14 26.10.1973.

3. Jean-Michel Leger // Resonance Magnetometer With Optical Pumping Using A Monolithic Laser // US Patent US 5,493,223 02/20/1996.

4. Bernard L. Upschulte, Steven J. Davis, Ludwig C. Balling, John J. Wright // Diode Laser-Pumped Magnetometer // US Patent US 6,472,869 B1, 10/29/2002 (prototype).

5. Alexandrov E.B., Zapassky V.S. Magnetic resonance in the noise spectrum of Faraday rotation // ZhETF, v. 81, no. 1, p. 132-138, 1981.

Claims (2)

1. A device for registering a magnetic field, containing an optical radiation source, a detection circuit located on the same optical axis, which consists of a polarizing element, a cell with atomic magnetic dipoles, a photodetector, to the output of which a measuring device is connected to register a magnetic field, characterized in that that the polarizing element is made linear, between the polarizing element and the cell with atomic magnetic dipoles on one optical axis there is a focusing lens, between the cell and the photodetector made in the form of a balanced photodiode there is a polarization divider and a refocusing lens, and a radio frequency analyzer is used as a measuring device spectrum with digital mathematical processing. 2. The device according to claim 1, characterized in that a laser diode with an internal resonator is used as a source of resonant radiation and a polarizing element.

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