SU1753380A1 - X-ray analyzer - Google Patents

Abstract

Use: creation of installations for high-precision express research of materials, including under special conditions (temperature, pressure, etc.). SUMMARY OF THE INVENTION: The detector 3, which scatters radiation, is connected to the input of the linear amplifier 4, to the output of which the input of the single-channel analyzer unit 7 is connected, the first (analog) input of the multiplying digital-to-analog converter 9 and the input of the second analog-digital converter 11. Output A multiplying digital analog converter 9 is connected to the input of the first analog-digital converter 5, the output of which is connected to the first input of a multi-channel analyzer 6. The output of a single-channel analysis torus 7 is connected to the first (informational) input of the scanner 8, the second (control) input of which is connected to the first output of the goniometer, and the output to the second input of the multichannel analyzer 6. The second (digital) input of the multiplying digital-analog converter 9 is connected to the output of the converter Code 10, whose input is connected to the second output of the goniometer 2, the output of the second analog-to-digital converter 11 is connected to the third input of the multi-modular analogue 6. The multiplying digital-to-analogue converter 9 passes an impulse The lines from the detector 3 (from the output of the linear amplifier 4), multiplying their amplitude by a factor determined by the digital code received from the converter of the code 10. At that, the functional dependence of AVyh Aex (sln # / sin00) is realized in relation to the amplitude A of pulses. where b9 is the initial and current angles, respectively. 1 il. V | about 00

Description

The invention relates to X-ray technology and can be used to create installations for high-precision, rapid investigation of materials, including under special conditions (temperature, pressure, etc.).

A device for X-ray diffractometry is known, which contains a source of laser radiation of another polychromatic X-ray radiation, a goniometer with a sample holder, a semiconductor detector with high energy resolution, a linear amplifier with an electromechanical converter, an analog-to-digital converter and a multichannel analyzer. The gain factor K of a linear amplifier due to the effect of an electromechanical transducer depends on the mutual angular position of the elements of the x-ray optical scheme (source - sample - detector's receiving slit) according to the law

to-to

KosIrT lu

where in - the current angle;

B0 is the initial angle between the sample plane and the plane passing through the axis of the detector's receiving slit. The detector is stationary during shooting, and the slot in front of it oscillates, scanning a small angular interval (within the sensitive area of the detector crystal).

The closest to the claimed technical entity is a device consisting of a source of polychromatic x-ray radiation, an automated geniometer with a sample holder, a semiconductor detector with high energy resolution, a linear amplifier, an analog-digital converter with discriminators at the input, and a multichannel analyzer. In this case, the output of the detector, which scatters X-rays in a scattered manner, is connected to the input of a linear amplifier, the output of which is connected to the input of an analog-digital converter, which is connected to the first (measuring) input of the analyzer by its output, the second (controlling) input of which is connected to the output goniometer.

The device can operate in two modes. In the first mode, the device is a conventional energy dispersive diffractometer, the survey in which is performed at constant angles between the sample, the source and the detector. The energy spectrum of the radiation scattered by the sample is accumulated in a digital form.

in the memory of a multichannel analyzer, from where it can later be transferred to an external tape or disk drive or display screen. In the second

In mode, the device is an angular diffractometer. For this, the thresholds of the discriminator of the analog-digital converter are tuned to transmit pulses from the detector, the amplitudes of which correspond to a narrow range of wavelengths, for example, the characteristic radiation of an x-ray source. Due to this, the detector, together with discriminators, additionally performs the function of a monochromator. The multichannel analyzer and goniometer in the second mode switch to synchronous scanning, respectively, of the channels in the analyzer and the angle in the goniometer, so

each channel number of the analyzer corresponds to a certain angle angle b, which determines the mutual angular position of the elements of the device (source, sample and detector). The filming is done during

scan time of a given range of angles (subject to the conditions of focusing x-rays on the detector). The synchronization of the operation of the goniometer and the analyzer is provided by an appropriate control link between them. As a result, the angular diffraction pattern is accumulated in the analyzer memory in a digital form, convenient for further use.

The drawbacks of the device are the absence of the possibility of simultaneous recording of energy dispersive and angular diffractograms, as a result of which the time of the experiment increases, and the impossibility of distinguishing diffraction and

fluorescent lines on the energy spectrum, typical of conventional energy dispersive analysis.

The purpose of the invention is to reduce the time of the experiment while maintaining accuracy and improving the distinction between diffraction and fluorescent lines in the energy spectrum without loss of information.

This goal is achieved by the fact that

a device for X-ray analysis, consisting of a source of collimated polychromatic radiation, an automated goniometer with a sample holder, a high energy resolution detector, a linear amplifier, a first analog-digital converter and a multi-channel analyzer, the output of the detector being connected to the output of a linear amplifier, and analog-to-digital converter output - with the first input of a multi-channel analyzer, a digital-to-analog converter is additionally introduced multiplying type, a code converter, a single-channel analyzer with amplitude discriminators at the input, a scanner and a second analog-to-digital converter, while the input of the single-channel analyzer, the first (analog) input of the multiplying digital-analog converter and the second analog-digital input are connected to the output of the linear amplifier converter, the output of the single-channel analyzer is connected to the first (informational) input of the scanner, the second (scanning) input of which is connected to the first output of the goniometer, and the output with the second input of the multi-channel analyzer, the second (digital) input of the multiplying digital-analog converter is connected to the output of the code converter, the input of which is connected.; to the second output of the goniometer, and the output of the multiplying digital-to-analog converter to the input of the first analog-digital converter, the output of the second analog-digital converter is connected to the third input of the multichannel analyzer.

The multiplying digital-to-analog converter transmits pulses from the detector (from the output of the linear amplifier), multiplying their amplitude by a factor determined by the digital code received from the code converter. In this case, with respect to the amplitude A of the pulses, a functional dependence is realized

dl

Avyh Avh11gg (2)

similar dependence (1) for a known device.

The introduction of additional blocks and new connections between the elements of the device made it possible to simultaneously store in the memory of a multichannel analyzer three diffraction patterns:

the angular distribution of the intensely scattered radiation in a given narrow wavelength range of the x-ray source;

a reduced energy spectrum (with reduction to a given initial angle B) with blurred fluorescent and selected diffraction lines;

an unreduced energy spectrum with blurred diffraction and highlighted fluorescent lines.

It is characteristic that all three spectra are obtained simultaneously (in parallel) during the scanning of a given angular interval by the angle in (while observing the Bragg-Brentano focusing geometry).

The possibility of simultaneously obtaining these two energy distributions allows one to obtain reliable information on the composition and structure of the sample and to reliably separate the diffraction and fluorescence maxima, and the angular

The diffractogram, taken in a narrow X-ray wavelength range, provides high accuracy in determining the linear parameters of the crystal lattice.

5 The drawing shows a block diagram of a device for X-ray structural analysis.

The device for X-ray analysis contains a source of collimated X-ray polychromatic radiation, an automated goniometer 2 with a sample holder, a detector 3 with high energy resolution, a linear amplifier 4, the first analog-digital

5 converter 5, a multichannel amplitude analyzer 6. In addition, the device contains a single-channel analyzer 7 with amplitude discriminators at the input, a sweep unit 8 multiplying a digital-to-tax converter 9, a code converter 10 and a second analog-to-digital converter 11 (similar to the first). The test sample is installed in the holder on the goniometer axis

5 2 in the path of the x-ray from source 1.

The detector 3, which perceives the radiation scattered by the sample, is connected to the input of the linear amplifier 4, to the output of which

0 connected to the input unit of the single-channel analyzer 7, the first (analog) input of the multiplying digital-to-analog converter 9 and the input of the second analog-digital converter 11, the output

5 multiplying digital-to-analog converter 9 is connected to the input of the first analog-digital converter 5, the output of which is connected to the first input of the multichannel analyzer 6, the output of the single analyzer 7 is connected to the first (informational) input of the scanner 8, the second (control) input of which is connected to the first exit of the goniometer, and the exit to the second entrance

5 of a multichannel analyzer 8, a second (digital) input of a multiplying digital-analog converter 9 is connected to the output of a code 10 converter, the input of which is connected to a second output of a goniometer 2, the output of a second analog-to-digital converter 11 is connected to the third input of a multichannel analyzer 6.

As an X-ray source 1, an X-ray tube with a copper or iron anode with a high-voltage power supply unit of the IRIS-6 type and a collimation gap can be used. As an automated goniometer 2, an automatic x-ray goniometer 721.OO.OO.OO.OO.OO. can be used. It provides scanning of the X-ray tube and the sample around the axis of the goniometer, respectively, at angles 2 in and in with respect to the fixed detector.

The autohiatic x-ray goniometer 721 A.00.00.00 consists of a goniometer control panel; communication systems with external devices; goniometer control systems; position control systems; drive control systems; the mechanism of angular movements of the goniometer shafts; mechanisms for adjusting the parameters of the x-ray flux of the system for remote control of the mechanisms.

As a detector 3, a semiconductor detector of the type BDRK with a high energy resolution can be used.

As a multichannel analyzer 6, a multichannel analyzer of the type LP 4900B from NOLIA with a set of its typical plug-in units can be used. Analyzer b provides the accumulation of spectral information in digital form, its display on the display screen and output to magnetic media with the possibility of subsequent mathematical processing, and also provides for the separation of the data memory into several zones with the accumulation of information from each source in its zone.

The following plug-in units of the analyzer LP 4900 V can be used to construct the circuit of the device proposed: as a linear amplifier 4 - a linear amplifier unit of the type LPA 4910.2; as a single-channel analyzer 7, a block of a single-channel analyzer LPB 4915, which contains amplitude discriminators of the lower and upper levels; as a scanning unit 8, a scaling and time scanning unit L PH 4913 used in an external trigger mode; As analog-digital converters 5, 11 - two blocks of analog-digital converter LPD 4911.11.

The corresponding setting of the plug-in blocks ensures that information from them is received in the desired memory area of the analyzer.

The multiplying digital-to-analog converter 9 can be implemented on the basis of an integrated circuit K 572 PA1A, which is a 10-bit digital-analog converter of a multiplying type.

The converter 10 code can be made on the basis of the microcontroller MS 2702 (Electronics K1-20), assembled on

microprocessor-based LSIs of the KR 580 series. It provides the reading of the current code of the angle 0 from the goniometer control unit, the entry and storage of the initial angle of the scan interval 0, the calculation and output to

real time relationship code s, on the second input multiplying

digital to analogue converter 9. Experimental studies

The proposed device for X-ray structural analysis showed that, compared with the known, complete separation of diffraction and fluorescent lines in the energy spectrum and reduction of the duration of the experiment while maintaining accuracy due to the simultaneous obtaining of the angular distribution for a narrow wavelength range of the X-ray source and two

energy distributions.

Claims (1)

Claims An X-ray k-ray analysis device comprising a source of collimated polychromatic x-ray radiation, an automated goniometer with a holder for the sample under study, a high energy resolution detector connected to the input of a linear amplifier, and a multichannel an analyzer, to the first input of which the output of the first analog-to-digital converter is connected, characterized in that, in order to reduce the time spent on performing the analysis while maintaining accuracy and improving the separation of diffraction and fluorescent lines in the energy spectrum, a multiplying digital-to-analog converter is additionally introduced into the device, goniometer angle code converter 0 to sin ratio code in I sin # 0. where in is the initial angle, in is the current angle, single-channel analyzer with amplitude discriminators of the lower and upper levels at the input, the scanner and the second analog-to-digital converter, the output of the linear amplifier is connected to the inputs of the single-channel analyzer, the second analog-digital converter and the analog input of the multiplying digital-analog converter, the output of the single-channel analyzer is connected to the information input of the scanner, the control input of which is connected to the output signal angular goniomet0 ra, and the output to the second input of the multichannel analyzer, the output of the multiplying zirro-analog converter is connected to the input of the first analog-digital converter, and the output of the second analog-to-digital converter - to the third input of the multichannel analyzer, the digital input of the multiplying digital-analog converter - with the output of the code converter whose input is connected to the goniometer angle code output.