CN201107265Y - Collinear femtosecond laser polarization pumping probe system - Google Patents
Collinear femtosecond laser polarization pumping probe system Download PDFInfo
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- CN201107265Y CN201107265Y CNU2007201904329U CN200720190432U CN201107265Y CN 201107265 Y CN201107265 Y CN 201107265Y CN U2007201904329 U CNU2007201904329 U CN U2007201904329U CN 200720190432 U CN200720190432 U CN 200720190432U CN 201107265 Y CN201107265 Y CN 201107265Y
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Abstract
The utility model relates to a detecting system of a polarizing pump with collinear femto-second laser. A detecting method comprises the steps that pulse laser is output through a polarization outputting pulse laser; the polarizing direction is rotated through a wave plate; a laser beam can be divided into two mutual vertical beams in the polarizing direction through a spectroscopic device; the laser beam is received and reflected through a reflector; the laser beam is modulated through an acousto-optic modulator; the modulating laser beam penetrates through a diaphragm; modulating signals are transmitted to the acousto-optic modulator through the driver of the acousto-optic modulator; an electronic control moving stage is shifted backward and forward; the vertical laser beam in the polarizing direction penetrates through a analyzer; the penetrated laser of the analyzer is received through a photo detector; a sample is fixed through a magnet fixing adjusting frame; the laser is illuminated on the surface of the sample through a focusing lens; the wave plate is fixed through an electronic control rotating stage. By the detecting system, two beams of vertical laser in the polarizing direction are merged into a beam of laser in the polarization coupling way; therefore, for the samples with different thickness, the two spatial coherent beams of laser on the sample can be all ensured, and the problem of adjusting the direction of the laser beam is avoided, so as to cause the operation to be simpler.
Description
Technical field
The utility model belongs to laser technology field, relates to ultrashort laser pulse pump probe technology, relates in particular to a kind of collinear femto-second laser polarized pump detecting system.
Background technology
Femtosecond laser pump probe system is that the continuous development and the maturation of ultrashort laser pulse technology makes people can explore the process that takes place in the utmost point short time, has important use to be worth in fields such as physics, chemistry, biology, medical science.In the ultrafast thermodynamic process of research, usually need be by ultra-short pulse laser pumping-detection technology.In traditional ultrashort laser pulse pumping-detection system, generally use beam of laser pumping, the different laser acquisition of other a branch of wavelength, therefore need to add nonlinear crystal and realize the optical maser wavelength conversion; Perhaps use the laser pump (ing) of a branch of level (or vertical), with the just the opposite light beam detection in other a branch of polarization direction, two-beam is with certain angle incident; Receive detection light with photodetector, signal is transferred to lock-in amplifier.Yet, when thickness of sample not simultaneously, pump light is also different with the position of focus detecting light on sample, makes the two-beam spatial independence; Just need regulate a branch of direction of light, the focus of two-beam is overlapped with manual or automatically controlled.Because the thickness of sample difference causes pump light and survey light spatially irrelevant, then need the imaging system of governor motion and spatial coherence monitoring usefulness in the prior art, make system architecture complexity and inconvenient operation.
Summary of the invention
In order to solve prior art problems, the purpose of this utility model is to solve the thickness of sample difference to cause pump light and survey the spatially incoherent shortcoming of light, feasible operation is simpler, reduced the imaging system of governor motion and spatial coherence monitoring usefulness simultaneously, for this reason, the utility model provides a kind of collinear femto-second laser polarized pump detecting system.
In order to realize described purpose, the technical scheme of a kind of collinear femto-second laser polarized pump detecting system of the utility model is: with the vertical light in two bundle polarization directions by the polarization coupling and mode, merge into a branch of light, its technical scheme is:
Polarization output pulsed laser, the pulse laser that is used to export;
First wave plate is used to receive the pulse laser that polarization is exported pulsed laser, and the polarization direction of pulse laser is rotated;
First light-splitting device is used for the rotary pulsed laser in the first wave plate polarization direction is divided into the mutually perpendicular two laser in polarization direction, and this two bundles laser is respectively the laser beam of horizontal direction polarization and the laser beam of vertical direction polarization;
Second wave plate receives the laser beam of the horizontal polarization of first light-splitting device, is used for the polarization direction of the laser beam of horizontal polarization is rotated;
Second light-splitting device receives the laser beam of horizontal polarization of the polarization direction rotation of second wave plate, is used for the laser beam of output polarization direction level;
First catoptron receives and reflects the laser beam of the polarization direction level of second light-splitting device;
Acousto-optic modulator receives and modulates the polarization direction horizontal laser beam of first mirror reflects, is used to export the modulating lasering beam of transmission;
Diaphragm is used to receive the modulating lasering beam of second catoptron;
Second catoptron, the modulating lasering beam of reception acousto-optic modulator transmission is used for the modulated laser beam steering with transmission;
First optical sensor receives the modulating lasering beam that sees through second catoptron, forms closed-loop control with the automatically controlled universal stage of fixing second wave plate;
Acoustooptic modulator driver, the laser beam of modulation transmitted sound photomodulator;
The 3rd light-splitting device is used for the laser beam of diaphragm incident is seen through and output fully;
Second optical sensor forms closed-loop control with the automatically controlled universal stage of fixing first wave plate, by the continuous power of regulating pump light and surveying light of outer computer control;
The 3rd catoptron is used to receive the deflection laser bundle that the 4th catoptron is regulated direction, makes the light beam that incides behind the 3rd light-splitting device from the 3rd catoptron overlap;
Automatically controlled transfer table moved along the direction of arrow by outer computer control, and moving direction is parallel with the laser direction that incides the 4th catoptron from first light-splitting device;
The 4th catoptron is used to receive the laser beam of first light-splitting device perpendicular to the surface level polarization, reflexes on the 3rd catoptron again, the polarization direction can not change, incide again on the 3rd light-splitting device by the 3rd catoptron,, reflected by the 3rd light-splitting device once more because incident is vertical polarization;
Photodetector is connected with outer computer, makes outer computer read signal from photodetector; Be used to receive the laser that analyzer sees through vertical polarization;
Analyzer is used to receive the scattered light of sample to the light generation of two kinds of polarization directions;
Magnet is adjustment rack fixedly, be used for that the 3rd catoptron is incided the 3rd light-splitting device and overlap light beam, conllinear incide the fixedly sample surfaces on the adjustment rack of magnet, make magnet fixedly the direction scope of the sample on the adjustment rack and incident beam spend to 90 0 and spend;
Condenser lens, reception is reflected once more perpendicular to the laser and the sample surfaces of irradiation on magnetic sample ferropexy adjustment rack of surface level polarization;
The first automatically controlled universal stage is used for fixing first wave plate, by outer computer control, with the same plane at the first wave plate place in rotate, sense of rotation be clockwise with counterclockwise two kinds;
The second automatically controlled universal stage is used for fixing second wave plate, by outer computer control, with the same plane at the second wave plate place in rotate, sense of rotation be clockwise with counterclockwise two kinds.
Preferably, polarization output pulsed laser is the femto second optical fiber laser of wavelength 780 nanometers or 1560nm, repetition frequency 100MHz, average power 30mW to 150mW, pulse width 100fs.
Preferably, first wave plate and second wave plate adopt 1/2nd wave plates.
Preferably, first light-splitting device, second light-splitting device and the 3rd light-splitting device adopt polarized light splitting device.
Preferably, first catoptron, second catoptron, the 3rd catoptron and the 4th catoptron adopt 45 degree laser mirrors.
Preferably, the modulating frequency 800Hz of acousto-optic modulator is to the 25MHz scalable, and frequency is controlled by acoustooptic modulator driver.
Preferably, the acoustooptic modulator driver frequency is controlled by outer computer, or works with the signal external trigger of data signal generator output.
Preferably, first optical sensor and second optical sensor adopt laser powermeter.
Preferably, automatically controlled nanometer of per steps 100 of transfer table full accuracy, 5 centimetres of sweep limits, corresponding optical delay scope is 300ps.
Preferably, photodetector is avalanche diode, photomultiplier, or charge coupled device ccd.
Preferably, the condenser lens focal length is 10mm to 100mm.
Technique effect of the present utility model or advantage: the utility model is restrainted the mode of the vertical light in polarization directions by polarization coupled with two, merges into a branch of light.Like this, to the sample of different-thickness, can both guarantee that two-beam space on sample is relevant, the problem of having avoided regulating beam direction; Feasible operation is simpler.
Description of drawings
Fig. 1 is the structural representation of the utility model embodiment
The critical piece explanation
1. polarization is exported pulsed laser;
2. first wave plate;
3. first light-splitting device;
4. second wave plate;
5. second light-splitting device;
6. first catoptron;
7. acousto-optic modulator;
8. diaphragm
9. second catoptron;
10. first optical sensor;
11. acoustooptic modulator driver;
12. the 3rd light-splitting device;
13. second optical sensor;
14. the 3rd catoptron;
15. automatically controlled transfer table;
16. the 4th catoptron;
17. photodetector;
18. analyzer;
19. magnet is adjustment rack fixedly;
20. condenser lens;
21. the first automatically controlled universal stage;
22. the second automatically controlled universal stage
Embodiment
Described in detail below in conjunction with 1 pair of the utility model of accompanying drawing, be to be noted that described embodiment only is intended to be convenient to understanding of the present utility model, and it is not played any qualification effect.
Application example
Shown in structural representation Fig. 1, polarization output pulsed laser 1 is the femto second optical fiber laser of wavelength 780 nanometers or 1560nm, repetition frequency 100MHz, pulse width 100fs, average power is 30mW or 50mW during wavelength 780 nanometers, and average power is 100mW or 150mW during wavelength 1560 nanometers.
First light-splitting device 3, second light-splitting device 5 and the 3rd light-splitting device 12 adopt first, second and the 3rd polarized light splitting device;
The modulating frequency 800Hz of acousto-optic modulator 7 is to the 25MHz scalable, and frequency is by acoustooptic modulator driver 11 controls;
First optical sensor 10 and second optical sensor 13 adopt laser powermeter;
Automatically controlled transfer table 15 full accuracies nanometer of per steps 100,5 centimetres of sweep limits, corresponding optical delay scope is 300ps.
Magnet fixedly adjustment rack 19 is combined by a magnet sucker and an iron base;
It is 10mm that condenser lens 20, difference as requested can be selected focal length, 50mm or 100mm;
The first automatically controlled universal stage 21 is fixed first wave plate 2, by outer computer control it is rotated in perpendicular;
The second automatically controlled universal stage 22 is fixed second wave plate 4, by outer computer control it is rotated in perpendicular.
First optical sensor 10 and second optical sensor 13 are laser powermeter, laser signal is converted to voltage signal, be read in the outer computer, the computing machine of the utility model outside drives automatically controlled transfer table 15 rotations again, up to arriving the power that the user sets again.
The following description of primary structure of the present utility model and principle:
Primary structure of the present utility model adopts laser power sensor, the 1/1st wave plate 2, first polarized light splitting device 3, second polarized light splitting device 5 and the 3rd polarized light splitting device 12 to form by polarization output pulsed laser 1, acousto-optic modulator 7, optical delay line, first optical sensor 10 and second optical sensor 13.
The pulse laser of polarization output pulsed laser 1 output by behind first polarized light splitting device 3, is divided into the mutually perpendicular two-beam in polarization direction with pulse laser again if linear polarization rotates by the 1/1st wave plate 2 rear polarizer directions; Rotate the 1/1st wave plate 2 by manual or automatically controlled way, can continuously change the strength ratio of two-beam.Incide on the 4 45 degree laser mirror 16 after perpendicular to the laser of surface level polarization by 3 reflections of first polarized light splitting device, reflex to again on the 3 45 degree laser mirror 14, the polarization direction can not change, incide again on the 3rd polarized light splitting device 12 by the 3 45 degree laser mirror 14, because incident is vertical polarization, be reflected once more perpendicular to the laser of surface level polarization, behind condenser lens 20, the sample surfaces of irradiation on magnetic sample ferropexy adjustment rack 19.Wherein, the 4 45 degree laser mirror 16 and the 3 45 degree laser mirror 14 are fixed on the automatically controlled transfer table 15, and automatically controlled transfer table 15 can be moved along the direction of arrow by outer computer control; And moving direction is vertical with incident laser direction, from the light beam of first polarized light splitting device the 3 to the 4 45 degree laser mirror and the parallel beam of the 3 45 degree laser mirror 14 to the 3rd polarized light splitting devices 12, guarantee that the facula position that automatically controlled transfer table 15 incides on the sample when moving forward and backward can not change.The light beam of the horizontal polarization by first polarized light splitting device 3 rotates by the 1/2nd wave plate 4 polarization directions after seeing through first polarized light splitting device 3 again, pass through second polarized light splitting device 5 again after, having only the polarization direction is that the light of level can pass through.Therefore, the 1/2nd wave plate 4 and second polarized light splitting device 5 constitute a power attenuation system.The one 45 degree laser mirror 6 receives by the laser of second polarized light splitting device 5 and the laser beam of polarization by reflection direction level; Acousto-optic modulator 7 receives and modulates the polarization direction horizontal laser beam of the one 45 degree laser mirror 6 reflections, is used to export the modulating lasering beam of transmission.Export the laser beam that the TTL signal modulates transmitted sound photomodulator 7 for acoustooptic modulation driver 11 by outer computer.Laser beam incident to the 2 45 degree catoptrons 9 of acousto-optic modulator 7 outputs deflect light beam.The modulating lasering beam of the 2 45 degree catoptron 9 outputs passes through diaphragm 8, and does not have modulated light beam can not pass through diaphragm 8.See through fully after light beam by diaphragm 8 incides the 3rd polarized light splitting device 12, focusing on sample surfaces by condenser lens 20.The light beam of the vertical polarization by the reflection of first polarized light splitting device 3 incides the 4 45 degree laser mirror 16, reflexes to the 3 45 degree laser mirror 14 again; Incide the 3rd polarized light splitting device 12 from the 3 45 degree laser mirror 14 laser light reflected bundles.By regulating the direction of the 2 45 degree laser mirror 9, make the light beam that incides behind the 3rd polarized light splitting device 12 from the 3 45 degree laser mirror 14 overlap, conllinear incide the fixedly sample surfaces on the adjustment rack 19 of magnet.The magnet fixedly direction scope of the sample on the adjustment rack 19 and incident beam is spent to 90 degree 0, and sample all produces scattering to the light of two kinds of polarization directions, behind analyzer 18, has only the light of vertical polarization to see through, and reenters to be mapped on the photodetector 17.
The rotation under first automatically controlled universal stage 21 controls of the 1/1st wave plate 2, the laser that passes through from the 1/1st wave plate 2 incides first polarized light splitting device 3; Second optical sensor 13 receives the laser beam that sees through the 3 45 degree laser mirror 14 after 3 reflections of first polarized light splitting device, and the 1/1st wave plate 2 and first polarized light splitting device 3 are combined into a cover power regulating system; Second optical sensor 13 and the automatically controlled universal stage 21 of fixing the 1/1st wave plate 2 are regulated the power of pump light and detection light continuously by closed-loop control by outer computer control.
The rotation under second automatically controlled universal stage 22 controls of the 1/2nd wave plate 4, the laser that passes through from the 1/2nd wave plate 4 incides the 2 45 degree laser mirror 9 via second light-splitting device 5, first catoptron 6 and acousto-optic modulator 7; First optical sensor 10, receive the modulating lasering beam that sees through the 2 45 degree laser mirror 9, the 1/2nd wave plate 4 and second polarized light splitting device 5 are formed the energy attenuation system, first optical sensor 10 and the automatically controlled universal stage 22 of fixing the 1/2nd wave plate 4 be by closed-loop control, by the outer computer control power of adjusting pump light continuously.
Optical delay line is made up of automatically controlled transfer table 15 and the 4 45 degree laser mirror the 16, the 3 45 degree laser mirror 14, and the delay scope determines that by the moving range of automatically controlled transfer table 15 the delay scope was 0 to 1 nanosecond in the example.
The effect of the 3rd polarized light splitting device 12 is that the different laser beam in two bundle polarization directions is merged into beam of laser, realizes the conllinear pump probe.
Acousto-optic modulator 7 and automatically controlled transfer table 15 and photodetector 17 synchronous operations, laser of acousto-optic modulator 7 outputs, automatically controlled transfer table 15 makes a move, and photodetector 17 is accepted laser, and outer computer reads a signal from photodetector 17.
The polarization laser of the output of polarization output pulsed laser 1 is divided into the orthogonal two-beam in polarization direction by the 1/1st wave plate 2 and first polarized light splitting device 3 with incident light, is respectively pump light and surveys light.Survey light by behind the lag line, turned to by the 3rd polarized light splitting device 12, focusing projects on the sample again.After high-power pump light passes through acousto-optic modulator 7 and aperture 8, by the 3rd polarized light splitting device 12 and the laser beam of surveying the synthetic a branch of conllinear of optocoupler.Optical delay line is made up of automatically controlled transfer table the 15, the 3 45 degree catoptron 14 and the 4 45 degree catoptron 16, and the delay scope determines that by the moving range of automatically controlled transfer table 15 the delay scope was 0 to 1 nanosecond in the example.
The effect of the 3rd polarized light splitting device 12 is that the different laser beam in two bundle polarization directions is merged into beam of laser, realizes the conllinear pump probe.
Acousto-optic modulator 7 and automatically controlled transfer table 15 and photodetector 17 synchronous operations, laser of acousto-optic modulator 7 outputs, automatically controlled transfer table 15 makes a move, and outer computer reads a signal from photodetector 17.Finally obtain scattering or the reflection strength of different time delays, the counter thermal characteristic of releasing material.
The above; it only is the embodiment in the utility model; but protection domain of the present utility model is not limited thereto; anyly be familiar with the people of this technology in the disclosed technical scope of the utility model; can understand conversion or the replacement expected; all should be encompassed in of the present utility model comprising within the scope, therefore, protection domain of the present utility model should be as the criterion with the protection domain of claims.
Claims (10)
1, a kind of collinear femto-second laser polarized pump detecting system is characterized in that, contains:
Polarization output pulsed laser, the pulse laser that is used to export;
First wave plate is used to receive the pulse laser that polarization is exported pulsed laser, and the polarization direction of pulse laser is rotated;
First light-splitting device is used for the rotary pulsed laser in the polarization direction of first wave plate is divided into the mutually perpendicular two laser in polarization direction, and this two bundles laser is respectively the laser beam of horizontal direction polarization and the laser beam of vertical direction polarization;
Second wave plate receives the laser beam of the horizontal polarization of first light-splitting device, is used for the polarization direction of the laser beam of horizontal polarization is rotated;
Second light-splitting device receives the laser beam of horizontal polarization of the polarization direction rotation of second wave plate, is used for the laser beam of output polarization direction level;
First catoptron receives and reflects the laser beam of the polarization direction level of second light-splitting device;
Acousto-optic modulator receives and modulates the polarization direction horizontal laser beam of first mirror reflects, is used to export the modulating lasering beam of transmission and the modulating lasering beam of reflection;
Second catoptron, the modulating lasering beam of reception acousto-optic modulator transmission is used for the modulated laser beam steering with transmission;
Diaphragm is used to receive the modulating lasering beam of second mirror reflects;
First optical sensor receives the modulating lasering beam that sees through second catoptron, forms closed-loop control with the automatically controlled universal stage of fixing second wave plate;
Acoustooptic modulator driver, the laser beam of modulation transmitted sound photomodulator;
The 3rd polarized light splitting device is used for the laser beam of diaphragm incident is seen through and output fully;
Second optical sensor forms closed-loop control with the automatically controlled universal stage of fixing first wave plate, by the continuous power of regulating pump light and surveying light of outer computer control;
The 3rd catoptron is used to receive the deflection laser bundle that the 4th catoptron is regulated direction, makes the light beam that incides behind the 3rd light-splitting device from the 3rd catoptron overlap;
Automatically controlled transfer table moved along the direction of arrow by outer computer control, and moving direction is parallel with the laser direction that incides the 4th catoptron from first light-splitting device;
The 4th catoptron, be used to receive the laser beam of first light-splitting device perpendicular to the surface level polarization, reflex to again on the 3rd catoptron, the polarization direction can not change, incide again on the 3rd light-splitting device by the 3rd catoptron, because incident is vertical polarization, laser is reflected by the 3rd polarized light splitting device once more;
Photodetector is connected with outer computer, makes outer computer read signal from photodetector; Be used to receive the laser that analyzer sees through vertical polarization;
Analyzer is used to receive the scattered light of sample to the light generation of two kinds of polarization directions;
Magnet is adjustment rack fixedly, be used for that the 3rd catoptron is incided the 3rd light-splitting device and overlap light beam, conllinear incide the fixedly sample surfaces on the adjustment rack of magnet, make magnet fixedly the direction scope of the sample on the adjustment rack and incident beam spend to 90 0 and spend;
Condenser lens, reception is reflected once more perpendicular to the laser and the sample surfaces of irradiation on magnetic sample ferropexy adjustment rack of surface level polarization;
The first automatically controlled universal stage is used for fixing first wave plate, by outer computer control, with the same plane at the first wave plate place in rotate, sense of rotation be clockwise with counterclockwise two kinds;
The second automatically controlled universal stage is used for fixing second wave plate, by outer computer control, with the same plane at the second wave plate place in rotate, sense of rotation be clockwise with counterclockwise two kinds.
2, according to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that polarization output pulsed laser is the femto second optical fiber laser of wavelength 780 nanometers or 1560nm, repetition frequency 100MHz, average power 30mW to 150mW, pulse width 100fs.
According to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that 3, first wave plate and second wave plate adopt 1/2nd wave plates.
According to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that 4, first light-splitting device, second light-splitting device and the 3rd light-splitting device adopt polarized light splitting device.
According to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that 5, first catoptron, second catoptron, the 3rd catoptron and the 4th catoptron adopt 45 degree laser mirrors.
6, according to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that, the modulating frequency 800Hz of acousto-optic modulator is to the 25MHz scalable, and frequency is controlled by outer computer, or works with the signal external trigger of data signal generator output.
According to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that 7, first optical sensor and second optical sensor adopt laser powermeter.
8, according to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that, automatically controlled nanometer of per steps 100 of transfer table full accuracy, 5 centimetres of sweep limits, corresponding optical delay scope is 300ps.
According to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that 9, photodetector is avalanche diode, photomultiplier, or charge coupled device ccd.
According to the described collinear femto-second laser polarized pump detecting system of claim 1, it is characterized in that 10, the condenser lens focal length is 10mm to 100mm.
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CNU2007201904329U CN201107265Y (en) | 2007-11-28 | 2007-11-28 | Collinear femtosecond laser polarization pumping probe system |
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CNU2007201904329U CN201107265Y (en) | 2007-11-28 | 2007-11-28 | Collinear femtosecond laser polarization pumping probe system |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101446687B (en) * | 2007-11-28 | 2010-07-07 | 中国科学院工程热物理研究所 | Collinear femto-second laser polarized pump detecting system |
CN102954952A (en) * | 2011-08-16 | 2013-03-06 | 亚历克斯·古谢夫 | Flash photolysis system |
CN107831120A (en) * | 2017-10-27 | 2018-03-23 | 中国人民解放军国防科技大学 | Polarization pump detection device |
-
2007
- 2007-11-28 CN CNU2007201904329U patent/CN201107265Y/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101446687B (en) * | 2007-11-28 | 2010-07-07 | 中国科学院工程热物理研究所 | Collinear femto-second laser polarized pump detecting system |
CN102954952A (en) * | 2011-08-16 | 2013-03-06 | 亚历克斯·古谢夫 | Flash photolysis system |
CN107831120A (en) * | 2017-10-27 | 2018-03-23 | 中国人民解放军国防科技大学 | Polarization pump detection device |
CN107831120B (en) * | 2017-10-27 | 2020-06-19 | 中国人民解放军国防科技大学 | Polarization pump detection device |
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