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CN201607406U - Laser probe micro-area component analyzer based on double laser light sources - Google Patents

Laser probe micro-area component analyzer based on double laser light sources Download PDF

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Publication number
CN201607406U
CN201607406U CN2010201194336U CN201020119433U CN201607406U CN 201607406 U CN201607406 U CN 201607406U CN 2010201194336 U CN2010201194336 U CN 2010201194336U CN 201020119433 U CN201020119433 U CN 201020119433U CN 201607406 U CN201607406 U CN 201607406U
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laser
semi
lens
wavelength
reflecting
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曾晓雁
陆永枫
郭连波
李常茂
蔡志祥
曹宇
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Huazhong University of Science and Technology
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Huazhong University of Science and Technology
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Abstract

The utility model belongs to the technical field of laser detection, and relates to a laser probe micro-area component analyzer based on double laser light sources in particular. The structure of the laser probe micro-area component analyzer based on double laser light sources is as follows: a fixed wavelength laser, an attenuator, a beam expander, a pore diaphragm and a first beam splitting mirror are arranged on the same horizontal light path in sequence; a wavelength tunable laser is reflected on the first beam splitting mirror through a second totally reflecting mirror and then shares the same light path with the fixed wavelength laser. The fixed wavelength laser and the wavelength tunable laser can be arranged up and down or in parallel; and the opening sequence and time delay of the fixed wavelength laser and the wavelength tunable laser can be controlled by a digital delay generator. Moreover, the collecting time of plasma spectrums which are received by a fiber probe, transmitted to a grating spectrometer by fibers and then transmitted to a reinforced CCD is also controlled by the digital delay generator. A laser detector excited by the double laser light sources has lower detection limit, high element analysis precision, good element selection, more stability and more reliability, and can be used for the accurate qualitative analysis and precise quantitative analysis on trace and micro elements of various substance micro-areas.

Description

A kind of component analyzer for laser probe micro-area based on double laser light source
Technical field
The utility model relates to a kind of component analyzer for laser probe micro-area that adopts double laser light source, is mainly used in the qualitative and accurate quantification analysis of material microcell elemental composition.
Background technology
Laser-induced Breakdown Spectroscopy (Laser Induced Breakdown Spectroscopy, abbreviation LIBS) technology is a kind of novel atomic spectroscopic analysis technology, it is to launch spectrum by pulse laser beam being focused on material surface ablation formation plasma, analyzes the composition and the content thereof of its element by gathering plasma spectrometry.Because it has unique synchronous real-time analytical capability of multielement, simple sample pretreatment requirement, particularly can realize the remote detection under field, real-time online and the high-risk environment, so qualitative, the quantitative test of this technology once occurring having received great concern and being widely used in various objects.The LIBS technology mainly shows the development trend of following two main aspects at present: one, aspect the macroscopic view detection: adopt the laser instrument of high-energy, short pulse that macroscopic material is surveyed, for example adopt nanosecond laser, or even femto-second laser, mainly be the analysis precision that reduces the LIBS detection limit and improve element.Two, LIBS, camera and worktable are combined make the component analyzer for laser probe micro-area of similar electron probe formula, make its microcell detecting function that possesses the electron probe formula, and all be better than electron probe instrument aspect detection accuracy, real-time analysis and the laser microcell.
The LIBS technology has significant technical advantage, and existing LIBS technology exists following deficiency again simultaneously, mainly comprises: the first, and detection limit is poor; The second, the interference of other elements, matrix effect influence; The 3rd, reliability is not high.(application number is 200910062846 to Chinese patent literature " a kind of component analyzer for laser probe micro-area ", open day is on November 25th, 2009) a kind of laser probe instrument based on the micro-area composition detection analysis disclosed, this laser probe instrument mainly is made up of LIBS, industrial CCD, worktable and control system, mainly be to survey at the analysis of material micro-area composition, because of it has adopted mechanical constraint mechanism, thereby reduced the detection limit of LIBS effectively; Adopt three-dimensional working platform simultaneously, add the coaxial optical system design, its original position analysis that can realize the material microcell is surveyed.But this component analyzer for laser probe micro-area still has the following disadvantages: the first, and use the individual pulse laser instrument not carry out sufficient resonant excitation by the article on plasma body, promptly the secondary excitation effect of its article on plasma body is undesirable; The second, adopt the inhibition that pulsed laser can not be in full force and effect and get rid of the interference of other elements, promptly can not well overcome the interference of matrix effect and other elements, can influence selectivity and reliability that its element is surveyed.The 3rd, the use of monopulse laser has limited the reduction of detection limit and the further raising of detection accuracy, can cause its detection to trace, trace element to exist than mistake.The utility model in two laser excitation light sources of being adopted can better replenish and improve technique scheme, compensate its defect.
Summary of the invention
For the various shortcoming that overcomes existing LIBS technology and exist based on the component analyzer for laser probe micro-area of surveying at microcell of LIBS technology, the utility model proposes a kind of component analyzer for laser probe micro-area based on double laser light source, the detection limit of this component analyzer for laser probe micro-area is low, ultimate analysis precision height, the element selectivity is good, and is more reliable and more stable.
A kind of component analyzer for laser probe micro-area based on double laser light source that the utility model provides is characterized in that: the light-emitting window of laser with fixed wavelength, attenuator, and beam expanding lens, aperture, first semi-transparent semi-reflecting lens are positioned on the same horizontal optical path successively; First total reflective mirror is movable to be installed, parallel with first semi-transparent semi-reflecting lens when it is positioned at light path; Focusing objective len is positioned on the reflected light path of first completely reflecting mirror; Second semi-transparent semi-reflecting lens is between first completely reflecting mirror and focusing objective len, perhaps between first completely reflecting mirror and first semi-transparent semi-reflecting lens;
Be placed with second total reflective mirror on the emitting light path of Wavelength tunable laser, the reflecting surface of second total reflective mirror and the angle of horizontal optical path are 45 degree, and first semi-transparent semi-reflecting lens is parallel with second total reflective mirror;
Industrial CCD is fixed on support bracket fastened top, and is positioned at the top of first completely reflecting mirror, and industrial CCD is connected with computing machine by cable; Support bracket fastened below is a traversing carriage, and the bottom of traversing carriage is equipped with the lens bracket rotating disk, has a plurality of lens brackets on the lens bracket rotating disk, and a focusing objective len all is installed on each lens bracket, the enlargement ratio difference of each focusing objective len;
The below of conglomeration camera lens is the two-dimemsional number controlled machine, and the two-dimemsional number controlled machine places on the base station;
The side of traversing carriage is equipped with screw mandrel and guide rail, and screw mandrel is connected with motor with guide rail, and Electric Machine Control screw mandrel and guide rail drive traversing carriage and move up and down along the z axle, constitute x-y-z three-axis moving system jointly with the two-dimemsional number controlled machine;
Fibre-optical probe is positioned on the reflected light path of second semi-transparent semi-reflecting lens, and is connected with grating spectrograph by optical fiber, and grating spectrograph is connected back access computing machine with enhancement mode CCD simultaneously;
Laser with fixed wavelength, Wavelength tunable laser link to each other with the digital delay generator respectively, and the digital delay generator is connected with enhancement mode CCD.
The component analyzer for laser probe micro-area based on double laser light source that the utility model provides (hereinafter to be referred as " laser probe instrument ") can reach the purpose that the accurate qualitative or accurate quantification of laser probe micro-area composition is analyzed.Particularly, the utlity model has following technical characterstic:
(1) the utility model adopts the fixed wave length pulsed laser to combine with Wavelength tunable laser, forms two laser excitation light sources.Why detection limit is low for traditional LIBS technology, analysis precision is not high, poor selectivity, can't get rid of the interference of other elements, one of its most critical factor is: under the monopulse LASER Light Source shooting conditions in the analyte the more element plasma light spectrum signal of content will fall into oblivion the less element spectral signal of content, therefore make that the detection limit of trace or trace element is higher, the constituent analysis precision reduces, and causes the selectivity variation at a certain concrete ultimate analysis the time.Cause the main cause of this phenomenon to be: present both at home and abroad LIBS system or can be used for the MicroLIBS system that microcell surveys and all just adopt single laser light source to excite, and the laser wavelength that uses is all fixed.And laser beam is when exciting the spectrum of material, there is very big difference in the degree that excites that different elements is subjected to being produced behind the different wave length laser beam irradiation in the material, and single LASER Light Source can't article on plasma body generation secondary excitation improve its plasma spectrometry signal intensity, also is difficult to effectively get rid of the interference of other elements simultaneously.
When the photon energy of laser beam is suitable with the intrinsic excitation energy needed that is detected material, the excitation of spectra intensity of this element is far longer than the excitation intensity of other element, like this, the spectral signal intensity that just can suppress other element, improve the spectral signal intensity that sets element, this excitation process is called resonant excitation, it is for the interference of getting rid of other elements, strengthen the selectivity that element is surveyed, reduce the detection limit of element, particularly significant for the analysis precision that increases substantially trace or trace element.The utility model has utilized this technical characterstic of material resonant excitation just, usually only adopt on the single laser with fixed wavelength basis at existing LIBS, increasing Wavelength tunable laser excites as resonant excitation light source composition double laser light source, thereby excite the characteristic spectrum of designed element in the analyte to greatest extent, characteristic spectrum with other element is suppressed to minimum simultaneously, quite tested element spectrum is amplified.This will reduce the detection limit of laser probe instrument greatly, the eliminating of maximum possible the interference of other elements, improved the analysis precision of element.
(2) on the basis of double laser light source simultaneously in conjunction with using plasma restraining structure technology, the fixed wave length pulsed laser inspires plasma at the material microcell, Wavelength tunable laser is carrying out resonant excitation to the plasma that has inspired again through after the desirable time-delay, can effectively overcome the influence of ground unrest like this, adopt custom-designed plasma confinement mechanism simultaneously, direction of motion and spreading range that can confining plasma, thereby prolong the existence life-span of plasma signal, reduce the element detectability, improve the precision of analyzed element, the application of double laser light source and constraint mechanism will make the detection limit of LIBS technology reduce greatly, and analysis precision improves greatly.。
(3) adopt beam expanding lens, aperture and focusing objective len to make the spot diameter of focussed laser beam littler.Adopt coaxial optical observation and Analytical System Design to finish home position observation and signals collecting simultaneously, on general LIBS basis, increase enhancement mode electric charge coupling detector (being enhancement mode CCD) and come spectral signal is carried out processing and amplifying.
In sum, compare with common LIBS technology and the MicroLIBS technology that can be used for the detection of material microcell, the laser probe instrument of this double laser light source has following technique effect:
The first, the detection limit of laser probe instrument is low, and analysis precision can be up to the ppm level, and its detection limit and analysis precision all will be far superior to electron probe instrument and scanning electron microscope;
The second, the laser probe instrument reaches below the 1 μ m the I of the excitation area of material, and its minimum space resolution is much better than electron probe, scanning electron microscope and MicroLIBS etc.;
The 3rd, the laser probe instrument is fit to the high precision micro-area composition of conduction and non-conductive material to be analyzed, and therefore, this equipment can be used to comprise the constituent analysis of nearly all solid matters such as metal, pottery, glass, plastics; And the general constituent analysis that only is fit to conductive material of electron probe, scanning electron microscope, and the general analysis precision only reaches a few percent;
The 4th, the laser probe instrument does not need vacuum, and the material sample size is unrestricted, and low to environmental requirement, and the real-time online detection analysis is carried out at the scene that can be transported to large parts;
At last, the extending space of laser probe instrument is big, can develop into serial special ingredient detecting instrument, and for example portable laser probe instrument satisfies the detection requirement of various objectives, particularly at the lossless detection of device.Therefore this double laser beam micro-area composition analyser can be widely used in various fields such as industry, agricultural, mining, safety detection.
Description of drawings
Fig. 1 is the structural representation of first kind of embodiment of the utility model component analyzer for laser probe micro-area;
Fig. 2 is the enlarged diagram of regional A among Fig. 1;
Fig. 3 is the structural representation of second kind of embodiment of the utility model component analyzer for laser probe micro-area;
Fig. 4 is the schematic top plan view of the parallel placement of double laser light source.
Embodiment
As shown in Figure 1, 2, the structure of the utility model component analyzer for laser probe micro-area is:
The light-emitting window of laser with fixed wavelength 1, attenuator 34, beam expanding lens 2, aperture 35, the first semi-transparent semi-reflecting lens 3 are positioned on the same horizontal optical path successively, the angle of the transmission plane of first semi-transparent semi-reflecting lens 3 and substrate 9 is 45 degree, also becomes miter angle with horizontal optical path simultaneously.Completely reflecting mirror 7 movable installations, parallel with first semi-transparent semi-reflecting lens 3 when it is positioned at light path.Second semi-transparent semi-reflecting lens 13 and focusing objective len 17 are positioned on the reflected light path of first completely reflecting mirror 7 successively.
Wavelength tunable laser 32 is positioned at the top of laser with fixed wavelength 1, is placed with second total reflective mirror 33 on its emitting light path, and second total reflective mirror 33 is parallel with first semi-transparent semi-reflecting lens 3.
Industrial CCD 6 is fixed on the top of fixed support 5, and is positioned at the top of first completely reflecting mirror 7, and industrial CCD 6 is connected with computing machine 24 by optical cable 20.Traversing carriage 12 is installed in the below of fixed support 5, the bottom of traversing carriage 12 is equipped with lens bracket rotating disk 15, have a plurality of lens brackets on the lens bracket rotating disk 15, a focusing objective len 17 all is installed on each lens bracket, the enlargement ratio difference of each focusing objective len 17 can carry out freely selecting by rotating mirror headstock rotating disk 15.
The below of conglomeration camera lens 17 is a two-dimemsional number controlled machine 19, and two-dimemsional number controlled machine 19 places on the base station 27.
The side of traversing carriage 12 is equipped with screw mandrel and guide rail 10, and screw mandrel is connected with motor 11 with guide rail 10.Motor 11 control screw mandrels and guide rail 10 drive traversing carriage 12 and move up and down along the Z axle, with two-dimemsional number controlled machine 19 (being the x-y axle), constitute the x-y-z three-dimensional motion system.
Fibre-optical probe 14 is positioned on the reflected light path of second semi-transparent semi-reflecting lens 13, and is connected with grating spectrograph 22 by optical fiber 21, and grating spectrograph 22 is connected back access computing machine 24 with enhancement mode CCD23 simultaneously.
Laser with fixed wavelength 1, Wavelength tunable laser 32 link to each other with digital delay generator 26 respectively, and digital delay generator 26 is connected with enhancement mode CCD23.
The main effect of laser with fixed wavelength 1 is the plasma that the high-octane pulse laser beam of emission inspires the material microcell, the effect of Wavelength tunable laser 32 is to carry out resonant excitation with the plasma to be detected that inspires, strengthen the spectral signal intensity of its feature plasma greatly, get rid of the interference of other element plasma signals.
Digital delay generator 26 is mainly used in the delay time between control laser with fixed wavelength 1 and the Wavelength tunable laser 32.Control the delay time that enhancement mode CCD23 opens the plasma spectrum signals collecting simultaneously.
Attenuator 34 laser beam energy that laser with fixed wavelength 1 inspires that is used to decay is with control with regulate laser with fixed wavelength 1 outgoing laser beam and make it reach desirable energy value.
The lasing beam diameter that beam expanding lens 2 is exported laser with fixed wavelength 1 enlarges, to reduce the angle of divergence of laser beam.Make full use of the numerical aperture of focusing objective len 17, focus on the back and obtain the littler laser beam spot of spot diameter, thereby improve the minimum space resolving accuracy of laser probe instrument.
Aperture 35 is used to eliminate the higher order mode of fixed wave length laser beam, keeps its low order 00 pattern.Make the energy distribution of fixed wave length laser beam more even.
Second total reflective mirror 33 is used for the laser beam of the Wavelength tunable laser output of glancing incidence is reflected vertically downward to first semi-transparent semi-reflecting lens 3.First semi-transparent semi-reflecting lens 3 is controlled by second rotary magnet 8, is mainly used in introducing Wavelength tunable laser laser beam and makes it and the same light path of fixed wave length laser beam.
The main effect of described industrial CCD 6: and focusing objective len 17 is together, constitutes the high power observing system of sample, is used for the observation analysis of sample surfaces pattern.By changing the distance between industrial CCD 6 and the focusing objective len 17, can change the surface topography enlargement ratio of observed sample on the display 25.
When completely reflecting mirror 7 is positioned on the laser optical path, with the reflection of laser beam horizontal optical path downwards, second semi-transparent semi-reflecting lens 13 can allow fixed wave length laser beam and Wavelength tunable laser laser beam see through, and the light signal of plasma can be reflected into simultaneously into optical fiber probe 14.
Described screw mandrel links to each other with motor 11 with guide rail 10, can move up and down at the driving lower edge of motor 11 Z axle, regulates focusing objective len 17 as required to the distance between the analyzed sample 31, makes the focus of laser beam always drop on the surface of analyzed sample 31.
The function of described focusing objective len 17 has three: one, Direct observation sample surfaces optical morphology.Two, as the part of light-conducting system, the surface of analyzed sample 31 will be shone directly into after the laser beam focusing.Three, gather plasma signal and enter fibre-optical probe 14 to second semi-transparent semi-reflecting lens, 13 back reflections, so that carry out spectral analysis along laser beam light path reverse transfer.
Described grating spectrograph 22 mainly is decomposed into plasma light the spectrum line of various elements, and described enhancement mode CCD23 mainly amplifies the signal of spectrum line, controls the acquisition time of plasma signal simultaneously.
Computing machine 24 can adopt desk-top computer or notebook computer to be connected with the signal acquisition processing circuit of enhancement mode CCD23 by USB interface or netting twine.The software of computing machine has autoscan, seeks functions such as atomic spectrum peak value, qualitative identification and Quantitative yield calculating.
Constraint mechanism 30 is another key mechanism of guaranteeing laser probe constituent analysis precision.Constraint mechanism 30 employed materials can be magnetic or nonmagnetic substance, adopt magnetic material can further prolong the life-span of plasma.Constraint mechanism 30 neither hinders the normal output of laser beam, does not stop that also the light signal of the plasma of induced with laser enters light-conducting system.Simultaneously, because constraint mechanism 30 is the less thin-wall constructions in space, again very near the surface of analyzed sample 31, therefore effectively the direction of motion and the speed of plasma confinement body prolong its existence life-span, the analysis precision of raising laser probe instrument.
The component analyzer for laser probe micro-area of double laser light source can satisfy qualitative analysis accurately of material microcell and accurate quantitative test, and its principle of work and process are as follows:
Completely reflecting mirror 7 is in the optical path states that departs from laser beam, and analyzed sample 31 is placed on the two-dimemsional number controlled machine 19.Adjust the height (z direction of principal axis) of two-dimemsional number controlled machine 19 focusing objective len 17 on the position of level (x-y direction of principal axis) and traversing carriage 12, and suitably adjust spacing between focusing objective len 17 and the industrial CCD 6, make analyzed sample 31 surfaces be on the focus of observing system, just can on display 25, observe and the surface microscopic topographic and the structure of analytic sample material.Aim at and lock the microcell of required analytic sample after the light path of three-dimensional work system and laser beam accurately mated.
After the feature microcell of analyzed sample 31 was aimed at and locked, the observation interface of switching display 25 was to assay surface.The switch that triggers first rotary magnet 4 makes first completely reflecting mirror 7 be arranged in the light path of laser beam and becomes miter angle with it.Open laser with fixed wavelength 1, make it to send the pulse laser beam of fixed wave length, the fixed wave length pulse laser beam decays to ideal value through attenuator 34 with its pulse energy, expand the bundle back by the higher order mode in the aperture 35 elimination laser beam through beam expanding lens 2 then, again by of the reflecting surface generation total reflection of first semi-transparent semi-reflecting lens, 3 backs at completely reflecting mirror 7, then by second semi-transparent semi-reflecting lens 13 after focusing objective len 17 focuses on the analyzed sample 31 ablates, produce plasma, plasma is the rapid expanding diffusion in constraint mechanism 30.
Digital delay generator 26 was delayed time to after the ideal time of setting, trigger the laser beam that Wavelength tunable laser 32 inspires the plasma wavelength of corresponding element to be detected, reflex to the reflecting surface of first semi-transparent semi-reflecting lens 3 through second total reflective mirror 33, after the first semi-transparent semi-reflecting mirror reflection with the same light path of fixed wave length laser beam, then pass through line focus object lens 17 focusing again of second semi-transparent semi-reflecting lens 13, beat at last on the plasma plume in constraint mechanism 30 by first total reflective mirror, 7 reflection backs.The laser beam that plasma plume one side and Wavelength tunable laser produce is carried out resonant excitation, strengthens the spectral signal of element to be detected greatly; The expansion diffusion of plasma plume in constraint mechanism 30 can produce shock wave on the other hand, shock wave reflects the diffusion of back extruding plasma plume on the constraint mechanism wall, make it generation extruding back and further produce secondary excitation, so strengthened isoionic spectral signal while not only but also prolonged the isoionic life-span.Resonant excitation and constraint structure function by double laser beam have reduced ground unrest, have improved signal to noise ratio (S/N ratio), have got rid of the interference of other elements, have strengthened the plasma light spectrum signal of element to be detected greatly.
The spectral signal that plasma discharges reflects at the lower surface of second semi-transparent semi-reflecting lens 13 by focusing objective len 17 backs, enter into fibre-optical probe 14, be coupled to the receiving end of optical fiber 21 then, by optical fiber 21 photon spectrum is input to grating spectrograph 22, and carry out the spectral signal processing and amplifying by enhancement mode CCD23, give computing machine 24 with related information transmission again, and show by the spectrum of display 25 with various wavelength, automatically discern various elemental compositions by computer software simultaneously, and calculate its content.
Below by by embodiment the utility model being described in further detail, but following examples only are illustrative, and protection domain of the present utility model is not subjected to the restriction of these embodiment.
Laser with fixed wavelength 1 adopts transfers the Q-Nd:YAG laser instrument, and its emission wavelength is 532nm, and the duration of pulse is 6ns, and pulse energy is about 200mJ.Wavelength tunable laser 32, its wavelength tuning range are that 215nm-2550nm is adjustable continuously, and the duration of pulse is 6ns; Single pulse energy is adjustable in 5-200mJ, pulse repetition rate 10Hz.Digital delay generator 26 models are DG535, and its delay resolution is 5Ps.
Laser with fixed wavelength 1, attenuator 34, beam expanding lens 2, aperture 35 all by screw connect directly be fixed on substrate 9 above.The top of laser with fixed wavelength 1 is installed Wavelength tunable laser 32, the first completely reflecting mirrors 7 and is installed on first rotary magnet 4, and first rotary magnet 4 links to each other with fixed support 5, and wherein fixed support 5 is fixedly mounted on the substrate 9.
Described substrate 9 is material such as marble or grouan preferably, guaranteeing its hardness and flatness, and has good damping, anti-seismic performance.
The below that second total reflective mirror, 33, the second total reflective mirrors 33 are installed in the side of fixed support 5 is that first semi-transparent semi-reflecting lens, 3, the first semi-transparent semi-reflecting lens 3 are parallel with first total reflective mirror 7, and first semi-transparent semi-reflecting lens 3 is between the beam expanding lens 2 and first total reflective mirror 7.
Traversing carriage 12 is installed below the fixed support 5, lens bracket rotating disk 15 is installed below the traversing carriage 12, on the lens bracket rotating disk 15 a plurality of lens brackets can be installed, gathering object lens all are installed on each lens bracket.This example is equipped with three lens brackets, and lens bracket inside is separately installed with focusing objective len 17.
The concrete operations step is as follows:
1. the gauge tap that first rotary magnet 4 is set makes completely reflecting mirror 7 be in the optical path states that departs from laser beam.
2. analyzed sample 31 is fixed on the two-dimemsional number controlled machine 19, observe the surface of analyzed sample 31 by industrial CCD 6, focusing objective len 17, adjust the height of focusing objective len 17 in two-dimemsional number controlled machine 19 and the traversing carriage 12, the microcell to be analyzed of sample is accurately located and locked by observing the back.
3, the switch of first rotary magnet 4 is triggered to assay surface in the observation interface of switching display 25, and completely reflecting mirror 7 is moved in the light path of laser beam.
4, opening laser with fixed wavelength 1 emission wavelength is the short pulse of 532nm, high-octane laser beam, the fixed wave length laser beam is carried out energy attenuation by attenuator 34 successively, beam expanding lens 2 expands bundle, aperture 35 is eliminated higher order mode, behind first semi-transparent semi-reflecting lens 3, reflect by second semi-transparent semi-reflecting lens 13 then at completely reflecting mirror 7 places, last line focus object lens 17 focus on analyzed sample 31 surfaces to the sample microcell generation plasma of ablating, and plasma spreads in constraint mechanism 30.
5. digital delay generator 26 external trigger Wavelength tunable lasers 32 inspire the laser beam of corresponding element wavelength to be detected.Laser beam is coaxial with the fixed wave length laser beam by first semi-transparent semi-reflecting lens, 3 backs by second total reflective mirror, 33 reflection backs, and reflection focuses on by focusing objective len 17 through second semi-transparent semi-reflecting lens 13 again and produces resonant excitation on the plasma plume on first total reflective mirror 7 successively.
6. plasma its corresponding element spectral signal after resonant excitation and constraint mechanism constraint will strengthen greatly, its spectral signal takes place at the lower surface of second semi-transparent semi-reflecting lens 13 that reflection is laggard goes into optical fiber probe 14, and fibre-optical probe 14 transfers to grating spectrograph 22 with the spectral signal that collects by silica fibre 21.
7. the atom and the ion spectra of 22 pairs of laser excitations of grating spectrograph are surveyed, are analyzed, detected spectral signal is passed through enhancement mode CCD23, enhancement mode CCD23 opens its spectra collection switch spectral signal is carried out desirable time delayed signal collection, and the spectral signal that collects is carried out processing and amplifying and be converted into electric signal being transferred to computing machine 24.
8. computing machine 24 is analyzed the spectral wavelength of element in the spectral wavelength that collects and the spectra database, analyzes and the composition and the content of definite microcell element, and shows by display 25.
By above-mentioned steps, just finished the accurate qualitative and accurate quantification analysis of fixed point composition of the component analyzer for laser probe micro-area of double laser light source.When needs are surveyed other feature microcells, by x, y, the control of z three-shaft linkage, the laser probe instrument is moved along the specimen surface profile, finish micro-area composition analysis to the sample different parts.
When the chemical constitution of sample surfaces is carried out line sweep and face scanning analysis, at first should program according to the surface topography of sample, required microcell area and path qualitative or quantitative test, note the laser opening time of laser with fixed wavelength when programming, the opening time of Wavelength tunable laser and enhancement mode CCD23 switch are gathered essential maintenance coordination in order between the isoionic time.Mobile, the spectral analysis process of laser instrument output high-power pulse laser beam and worktable all must be coordinated to carry out simultaneously, with line sweep, the face scanning constituent analysis of finishing sample surfaces.
The utility model can also adopt embodiment as shown in Figure 3, for example second semi-transparent semi-reflecting lens 13 can be moved between first semi-transparent semi-reflecting lens 3 and first completely reflecting mirror 7, and first completely reflecting mirror 7 and the 13 parallel installations of second semi-transparent semi-reflecting lens, fibre-optical probe 14 is as for the top of second semi-transparent semi-reflecting lens 13.
Simultaneously, laser with fixed wavelength 1 can parallelly be placed with Wavelength tunable laser 32, first semi-transparent semi-reflecting lens 3 and second total reflective mirror 33 all are vertically mounted on the upper surface of substrate 9 during parallel the placement, the reflecting surface of second total reflective mirror 33 becomes miter angle with horizontal optical path, this moment first semi-transparent semi-reflecting lens 3 and the 33 parallel installations of second total reflective mirror, its vertical view is as shown in Figure 4.
For complex-shaped sample, can also on the two-dimemsional number controlled machine, increase a rotary small-sized worktable, it can rotate as rotation axis with A axle that is parallel to the x axle or the B axle that is parallel to the y axle, and with the motion of three axles of x-y-z interlock, become five-axle linkage system, therefore can make hang down all the time as for sample analyzed of the incident direction of laser beam, guarantee the intensity and the analysis precision of the plasma photosignal of gathering.
Three-dimensional work system also can directly adopt three-dimension numerical controlled lathe.
The utility model component analyzer for laser probe micro-area has the material microcell is carried out the precision detection function, it is to the location Aligning degree height of material microcell, can satisfy the chemical constitution and the material phase analysis requirement of large-scale metallic element, ceramic parts, macromolecular material parts to the surface topography of thing phase, the accurate quantification analysis that micro-structural feature carries out micro-area composition.
The above is preferred embodiment of the present utility model, but the utility model should not be confined to the disclosed content of this embodiment and accompanying drawing.So everyly do not break away from the equivalence of finishing under the spirit disclosed in the utility model or revise, all fall into the scope of the utility model protection.

Claims (3)

1. component analyzer for laser probe micro-area based on double laser light source, it is characterized in that: the light-emitting window of laser with fixed wavelength (1), attenuator (34), beam expanding lens (2), aperture (35), first semi-transparent semi-reflecting lens (3) is positioned on the same horizontal optical path successively; Completely reflecting mirror (7) is movable to be installed, parallel with first semi-transparent semi-reflecting lens (3) when it is positioned at light path; Focusing objective len (17) is positioned on the reflected light path of first completely reflecting mirror (7); Second semi-transparent semi-reflecting lens (13) is positioned between first completely reflecting mirror (7) and the focusing objective len (17), perhaps between first completely reflecting mirror (7) and first semi-transparent semi-reflecting lens (3);
Be placed with second total reflective mirror (33) on the emitting light path of Wavelength tunable laser (32), the reflecting surface of second total reflective mirror (33) and the angle of horizontal optical path are 45 degree, and first semi-transparent semi-reflecting lens (3) is parallel with second total reflective mirror (33);
Industrial CCD (6) is fixed on the top of fixed support (5), and is positioned at the top of first completely reflecting mirror (7), and industrial CCD (6) is connected with computing machine (24) by optical cable (20); The below of fixed support (5) is traversing carriage (12), the bottom of traversing carriage (12) is equipped with lens bracket rotating disk (15), the lens bracket rotating disk has a plurality of lens brackets on (15), a focusing objective len (17) all is installed, the enlargement ratio difference of each focusing objective len (17) on each lens bracket;
The below of conglomeration camera lens (17) is two-dimemsional number controlled machine (19), and two-dimemsional number controlled machine (19) places on the base station (27);
The side of traversing carriage (12) is equipped with screw mandrel and guide rail (10), screw mandrel is connected with motor (11) with guide rail (10), motor (11) control screw mandrel and guide rail (10) drive traversing carriage (12) and move up and down along the z axle, constitute x-y-z three-axis moving system jointly with two-dimemsional number controlled machine (19);
Fibre-optical probe (14) is positioned on the reflected light path of second semi-transparent semi-reflecting lens (13), and is connected with grating spectrograph (22) by optical fiber, and grating spectrograph (22) is connected back access computing machine (24) with enhancement mode CCD (23) simultaneously;
Laser with fixed wavelength (1), Wavelength tunable laser (32) link to each other with digital delay generator (26) respectively, and digital delay generator (26) is connected with enhancement mode CCD (23).
2. the component analyzer for laser probe micro-area based on double laser light source according to claim 1 is characterized in that:
Wavelength tunable laser (32) is positioned at the top of laser with fixed wavelength (1), and the angle of the upper surface of the transmission plane of first semi-transparent semi-reflecting lens (3) and substrate (9) is 45 degree.
3. the component analyzer for laser probe micro-area based on double laser light source according to claim 1 is characterized in that:
Laser with fixed wavelength (1) and the parallel placement of Wavelength tunable laser (32), first semi-transparent semi-reflecting lens (3) is vertically mounted on the upper surface of substrate (9).
CN2010201194336U 2010-02-10 2010-02-10 Laser probe micro-area component analyzer based on double laser light sources Expired - Lifetime CN201607406U (en)

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CN104181110A (en) * 2014-08-15 2014-12-03 中国科学院上海技术物理研究所 Laser dual-modulation reflection spectrum detection system based on microscope
CN104502315A (en) * 2014-12-02 2015-04-08 中国科学院半导体研究所 Micro-region fluorescent scanning measurement system
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Publication number Priority date Publication date Assignee Title
CN103512868A (en) * 2013-09-10 2014-01-15 华中科技大学 Micro-domain laser probe component analyzer based on optical fiber waveguide
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