CN203705371U - X-ray spectrometer for measuring all elements - Google Patents
X-ray spectrometer for measuring all elements Download PDFInfo
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- CN203705371U CN203705371U CN201420071215.8U CN201420071215U CN203705371U CN 203705371 U CN203705371 U CN 203705371U CN 201420071215 U CN201420071215 U CN 201420071215U CN 203705371 U CN203705371 U CN 203705371U
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Abstract
The utility model relates to an X-ray spectrometer for measuring all elements. The X-ray spectrometer comprises a point light source X-ray tube and high-voltage power supply, a capillary X-ray lens, a five-dimensional sample mobile station, an electron beam emitted from an electron gun, an optical microscope, a capillary X-ray pellicle mirror, a semi-conductor X-ray detector and electronics system and a vacuum cavity, wherein a double excitation source consisting of micro-beam X-ray beams generated by focussing of the 5-10 kv low-voltage electron beam and the capillary X-ray lens is adopted; after X-rays of the element characteristics are filtered by the capillary X-ray pellicle mirror, the X-rays of the element characteristics enter an X-ray detector; after being treated by electronics systems, such as a pre-amplifier, a main magnifier, a multi-channel analyzer and the like, generated signals are displayed and stored in a computer. Therefore, high-precision element content determination can be performed, meanwhile, the measurement and analysis of all the elements are realized.
Description
Technical field
The utility model relates to a kind of x-ray fluorescence analysis spectrometer, is specifically related to a kind of X ray spectrometer of measuring full element.
Background technology
The XRF spectrometer of electron-beam excitation, as Fig. 1, the general annex as scanning electron microscope, generally for measuring the elemental composition of granule sample or the element scanning analysis of sample small size.
But there is following shortcoming in the XRF spectrometer of electron-beam excitation: 1, the spectral line that electron beam is less than potassium element K α (3.3keV) to characteristic X-ray energy has higher launching efficiency, as the K α line of the light elements such as C, N and O; But the launching efficiency that characteristic energy is greater than to potassium element K α (3.3keV) is lower, therefore for Rb, Sr, Y in Soil and Rock, Zr trace element, can only rely on L line to measure, and analytical error is very large; The background ratio of the bremstrahlen of electron-beam excitation sample generation is simultaneously higher, causes the accuracy of measurement data also not high, generally can only do qualitatively and analyze; 2, electron beam penetrates the degree of depth of sample and only has tens microns, generally can only do the analysis of sample surfaces; 3, it is generally inhomogeneous that element distributes in sample, and the hot spot of electron beam is generally no more than 10 microns, the sample that is greater than 100 microns for particle diameter, and the data in 10 microns of regions of a measurement can not represent the analysis data of whole particulate samples; 4, in general Electronic Speculum, in the X ray excited fluorescence analysis sample of electron beam, element composition generally carries out under the voltage of 20kV, and high voltage affects the sharpness of secondary electron imaging; 5, for the sample of nonconductor, need to plate layer of metal film to avoid the accumulation of electric charge to affect the sharpness of secondary electron imaging at sample surfaces.
Simultaneously, x-ray fluorescence analysis spectrometer is the important analytical approach of constituent content in the various samples of a kind of nondestructive analysis, how many differentiations its element kind and constituent content of the characteristic energy that middle element sends per sample and peak area, the spectral line of its element more than potassium to characteristic X-ray energy has higher launching efficiency.But also there is following defect in existing x-ray fluorescence analysis spectrometer: 1, conventional x-ray fluorescence analysis spectrometer, in the high-energy X ray situation of being excited, ray easily involves the region of focus periphery and impacts, and makes measuring accuracy become problem, 2, patent of invention 200710148846.X discloses a kind of X-ray analysis equipment, mainly to have added an aperture or slit before converging x-ray lens the kapillary that converges X ray focused spot diameter hundreds of micron is micro-, object is to solve the micro-x-ray lens that converges of kapillary to converge focal spot size and the energy distribution problem that X ray forms, further improve precision, but, before capillary X-ray lens, adding aperture or slit is that the hot spot that irradiates sample can reach below 100 microns on the one hand, the negative effect causing is to have reduced the intensity of irradiating the X ray of sample, mainly the intensity of low-energy X-ray, more be unfavorable for exciting of light element in sample.
Therefore, based on the defect of above-mentioned prior art, at present also cannot be by correlation means by two kinds of instruments in conjunction with to realize the measurement of full element.
Summary of the invention
In order to solve the defect and the problem that exist in above-mentioned prior art, the utility model proposes a kind of X ray spectrometer of measuring full element, it can carry out high-precision constituent content mensuration, realizes the Measurement and analysis of full element simultaneously, and equipment is simple.
The utility model is achieved through the following technical solutions:
Described X ray spectrometer comprises:
Pointolite X-ray tube and high-voltage power supply, capillary X-ray lens, five dimension sample transfer tables, the electron beam that electron gun sends, optical microscope, capillary X-ray semi-permeable mirror, X-ray semiconductor detector and electronic system and vacuum cavity; Wherein, pointolite X-ray tube and high-voltage power supply, optical microscope and X-ray semiconductor detector and electronic system are fixed on the outer wall of vacuum cavity; Capillary X-ray lens, five dimension sample transfer tables, the electron beam that electron gun sends and capillary X-ray semi-permeable mirror are arranged on the inside of vacuum cavity;
Described pointolite X-ray tube and high-voltage power supply are positioned at the oblique upper in the left side of five dimension sample transfer tables, described pointolite X-ray tube becomes miter angle with surface level, the X ray sending by capillary X-ray lens with the angular illumination of 45 degree on the samples to be detected on described five dimension mobile platforms;
Described electron beam is 5-10kV denoted low voltage electron beam, on the microcell of vertical irradiation on sample;
Described capillary X-ray semi-permeable mirror becomes the angle of 38 ° to accept the characteristic X-ray that in sample, element inspires with surface level, it is positioned at the front end of X-ray semiconductor detector and electronic system, and the smaller diameter end of capillary X-ray semi-permeable mirror is aimed at described sample film micro area to be detected, larger diameter end is aimed at X-ray semiconductor detector and electronic system, X ray enters hollow glass tube to meet in the angle of hollow glass inside pipe wall transmitting total reflection from the smaller diameter end of capillary X-ray semi-permeable mirror, mode in the smooth inner wall total reflection of hollow glass tube is transmitted in the inside of glass capillary,
Described X-ray semiconductor detector and electronic system receive the X ray after described capillary X-ray semi-permeable mirror filters, and the signal of generation, after electronic system is processed, shows and is stored in computing machine;
Described in computer control, five dimension sample moving platforms can move or rotate sample, so that find fast tested film micro area, and make the position of described sample be positioned at the position at optical microscope focus point center.
Further, described high-voltage power supply is 40-50kV.
Further, described capillary X-ray lens will pool the focal spot of diameter in 30-100 micron left and right from X-ray tube X ray out.
Further, the focused spot diameter of described electron beam is 10 microns.
Further, described electronic system comprises prime amplifier, main amplifier and multichannel analyzer.
The utility model provides the beneficial effect of technical scheme to be:
1, solve the full elements are contained problem from B to U from sample, can the hydrocarbon oxygen of high efficiency measurement boron etc. light element, also can accurately measure the heavy metal elements such as U; Be less than the elemental characteristic K spectral line of potassium element with electron beam excited sample Atom ordinal number, and the excitation of X-rays focusing on kapillary is measured feature K or L spectral line that sample Atom ordinal number is greater than potassium element.
2, the bremstrahlen that utilizes the front kapillary semi-permeable mirror filtering electronic of X-ray detector and X ray bombardment sample to produce enters X-ray detector, reduces the background of power spectrum, improves the analysis precision of data.
3. the electron beam that adopts X ray and low-voltage, charge accumulated is fewer, moreover, adopt observation by light microscope sample surfaces and without secondary electron detector, therefore for non-conductive sample, without metal-coated membrane.
4, solving X ray has the penetration depth of hundreds of micron and focused spot diameter to be greater than 30 microns of above particle sizings, and analysis data can represent the data of whole sample.
Brief description of the drawings
Fig. 1 is the XRF spectrometer structural representation of electron-beam excitation in prior art
Fig. 2 is the utility model structural representation
Main description of reference numerals:
1, pointolite X-ray tube and high-voltage power supply; 2, capillary X-ray lens; 3, five dimension sample transfer tables; 4, the electron beam that electron gun sends; 5, optical microscope; 6, capillary X-ray semi-permeable mirror; 7, X-ray semiconductor detector and electronic system; 8, vacuum cavity.
Embodiment
Pointolite X-ray tube and high-voltage power supply (1) are positioned at the oblique upper in the left side of five dimension sample transfer tables (3), described pointolite X-ray tube becomes miter angle with surface level, the X ray sending by capillary X-ray lens (2) with the angular illumination of 45 degree on the samples to be detected on described five dimension mobile platforms (3);
Described electron beam (4) is 8-10kV denoted low voltage electron beam, on the microcell of vertical irradiation on sample;
Described capillary X-ray semi-permeable mirror (6) becomes the angle of 38 ° to accept the characteristic X-ray that in sample, element inspires with surface level, it is positioned at the front end of X-ray semiconductor detector and electronic system (7), and the smaller diameter end of capillary X-ray semi-permeable mirror (6) is aimed at described sample film micro area to be detected (9), larger diameter end is aimed at X-ray semiconductor detector and electronic system (7), X ray enters hollow glass tube to meet in the angle of hollow glass inside pipe wall transmitting total reflection from the smaller diameter end of capillary X-ray semi-permeable mirror (4), mode in the smooth inner wall total reflection of hollow glass tube is transmitted in the inside of glass capillary,
Described X-ray semiconductor detector and electronic system (7) receive the X ray after described capillary X-ray semi-permeable mirror (6) filters, and the signal of generation, after electronic system is processed, shows and is stored in computing machine;
Described in computer control, five dimension sample moving platforms (3) can move or rotate sample, so that find fast tested film micro area, and make the position of described sample be positioned at the position at optical microscope (5) focus point center.
The utility model is implemented in the following manner:
Referring to accompanying drawing 2, on the interface of scanning electron microscope, configure the micro-beam X-ray bundle of X-ray tube (OXFORD company of the U.S., molybdenum target, 50 watts, 36 microns × 36 microns of focal spot sizes) and capillary X-ray lens composition.Adopt two excitaton sources of the micro-beam X-ray Shu Zucheng of low voltage electron beam 5-10kv and kapillary X-tube lens focus, it is front that capillary X-ray lens are fixed on microfocus X-ray tube (1), will pool from X-ray tube X ray out diameter at the focal spot of 30-100 micron left and right, with surface level angular illumination at 45 ° on the microcell of sample; And 10 microns of the focused spot diameters of electron beam, vertical is radiated on the microcell on sample.The measuring position of sample is observed by optical microscope (enlargement factor 0-3000 doubly), and the position of sample is positioned at the position at optical microscope focus point center.Kapillary semi-permeable mirror is integrated on Amptek SDD X-ray detector, and the angle that forms 38 ° with level is accepted the characteristic X-ray that in sample, element inspires.Elemental characteristic X ray, after kapillary semi-permeable mirror, then enters Amptek SDD X-ray detector, and the signal of generation, after the electronic systems such as prime amplifier, main amplifier and multichannel analyzer are processed, shows and is stored in computing machine.
The above; it is only preferred implementation of the present utility model; but protection domain of the present utility model is not limited to this; those skilled in the art should understand that; limit the principle of the present utility model and spirit of its scope in the case of not departing from by claim and equivalent thereof; can modify and perfect to these embodiment, these amendments and improve also should be in protection domain of the present utility model.
Claims (5)
1. an X ray spectrometer of measuring full element, is characterized in that, described X ray spectrometer comprises:
Pointolite X-ray tube and high-voltage power supply (1), capillary X-ray lens (2), five dimension sample transfer tables (3), the electron beam (4) that electron gun sends, optical microscope (5), capillary X-ray semi-permeable mirror (6), X-ray semiconductor detector and electronic system (7) and vacuum cavity (8); Wherein, pointolite X-ray tube and high-voltage power supply (1), optical microscope (5) and X-ray semiconductor detector and electronic system (7) are fixed on the outer wall of vacuum cavity; Capillary X-ray lens (2), five dimension sample transfer tables (3), the electron beam (4) that electron gun sends and capillary X-ray semi-permeable mirror (6) are arranged on the inside of vacuum cavity (8);
Described pointolite X-ray tube and high-voltage power supply (1) are positioned at the oblique upper in the left side of five dimension sample transfer tables (3), described pointolite X-ray tube becomes miter angle with surface level, the X ray sending by capillary X-ray lens (2) with the angular illumination of 45 degree on the samples to be detected on described five dimension mobile platforms (3);
Described electron beam (4) is 5-10kV denoted low voltage electron beam, on the microcell of vertical irradiation on sample;
Described capillary X-ray semi-permeable mirror (6) becomes the angle of 38 ° to accept the characteristic X-ray that in sample, element inspires with surface level, it is positioned at the front end of X-ray semiconductor detector and electronic system (7), and the smaller diameter end of capillary X-ray semi-permeable mirror (6) is aimed at described sample film micro area to be detected (9), larger diameter end is aimed at X-ray semiconductor detector and electronic system (7), X ray enters hollow glass tube to meet in the angle of hollow glass inside pipe wall transmitting total reflection from the smaller diameter end of capillary X-ray semi-permeable mirror (4), mode in the smooth inner wall total reflection of hollow glass tube is transmitted in the inside of glass capillary,
Described X-ray semiconductor detector and electronic system (7) receive the X ray after described capillary X-ray semi-permeable mirror (6) filters, and the signal of generation, after electronic system is processed, shows and is stored in computing machine;
Described in computer control, five dimension sample moving platforms (3) can move or rotate sample, so that find fast tested film micro area, and make the position of described sample be positioned at the position at optical microscope (5) focus point center.
2. a kind of X ray spectrometer of measuring full element as claimed in claim 1, is characterized in that, described high-voltage power supply is 40-50kV.
3. a kind of X ray spectrometer of measuring full element as claimed in claim 1, is characterized in that, described capillary X-ray lens (2) will pool the focal spot of diameter in 30-100 micron left and right from X-ray tube X ray out.
4. a kind of X ray spectrometer of measuring full element as claimed in claim 1, is characterized in that, the focused spot diameter of described electron beam (4) is 10 microns.
5. a kind of X ray spectrometer of measuring full element as claimed in claim 1, is characterized in that, described electronic system comprises prime amplifier, main amplifier and multichannel analyzer.
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420071215.8U CN203705371U (en) | 2014-02-19 | 2014-02-19 | X-ray spectrometer for measuring all elements |
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| CN201420071215.8U CN203705371U (en) | 2014-02-19 | 2014-02-19 | X-ray spectrometer for measuring all elements |
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103808747A (en) * | 2014-02-19 | 2014-05-21 | 北京师范大学 | X-ray spectrometer for measuring total elements |
| CN104897705A (en) * | 2015-06-26 | 2015-09-09 | 北京师范大学 | X-ray diffraction spectrometer and method for recognizing types of liquids |
| CN106646585A (en) * | 2017-01-24 | 2017-05-10 | 中国工程物理研究院激光聚变研究中心 | Quasi-monoenergetic X-ray calibration platform |
| CN112595703A (en) * | 2020-12-09 | 2021-04-02 | 黄善杰 | Electron beam excited semiconductor luminescence performance test platform and excitation parameter optimization method |
-
2014
- 2014-02-19 CN CN201420071215.8U patent/CN203705371U/en not_active Expired - Fee Related
Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103808747A (en) * | 2014-02-19 | 2014-05-21 | 北京师范大学 | X-ray spectrometer for measuring total elements |
| CN103808747B (en) * | 2014-02-19 | 2016-11-09 | 北京师范大学 | A kind of X-ray spectrometer measuring full element |
| CN104897705A (en) * | 2015-06-26 | 2015-09-09 | 北京师范大学 | X-ray diffraction spectrometer and method for recognizing types of liquids |
| CN104897705B (en) * | 2015-06-26 | 2019-05-21 | 北京师范大学 | A kind of X-ray diffraction spectrometer and method identifying class of liquids |
| CN106646585A (en) * | 2017-01-24 | 2017-05-10 | 中国工程物理研究院激光聚变研究中心 | Quasi-monoenergetic X-ray calibration platform |
| CN106646585B (en) * | 2017-01-24 | 2023-12-22 | 中国工程物理研究院激光聚变研究中心 | Quasi-monoenergetic X-ray calibration platform |
| CN112595703A (en) * | 2020-12-09 | 2021-04-02 | 黄善杰 | Electron beam excited semiconductor luminescence performance test platform and excitation parameter optimization method |
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| CF01 | Termination of patent right due to non-payment of annual fee | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20140709 Termination date: 20160219 |