Журнал Российского общества по неразрушающему контролю и технической диагностике
The journal of the Russian society for non-destructive testing and technical diagnostic
 
| Русский Русский | English English |
 
Главная
23 | 11 | 2024
2020, 12 December

DOI: 10.14489/td.2020.12.pp.044-048

Lelyukhin A. S., Muslimov D. A.
APPLICATION OF POSITION-SENSITIVE DETECTORS FOR ANALYZING THE ENERGY SPECTRA OF PHOTON RADIATION
(pp. 44-48)

Abstract. Monitoring the spectral composition of photon radiation from generating sources and emitting objects is the most informative way to analyze the radiation fields created by them. However, it is impossible to study the radiation characteristics of radiation fields of ultra short duration and high intensity using direct measurement methods. This work considers a method for reconstructing the spectral distributions of photon radiation from the profile of the secondary radiation fields recorded by a position-sensitive detector. To implement a new method of measurement in the primary beam of radiation is an extended scattering body of homogeneous material. Outside the field of the primary beam, a position-sensitive detector is placed along the generatrix of the scattering body, which records the photons of the secondary radiation and the coordinates of their emission. The spectral composition of the primary radiation beam is restored from the shape of the spatial distribution obtained. To find a quasi-solution describing the energy spectrum of the primary radiation beam, it is proposed to use the maximum likelihood expectation maximization method. The possibility of switching to measurements in secondary radiation fields having a lower intensity is confirmed by the experimental results. To form secondary radiation fields, we used a composite phantom containing three scattering bodies in the form of rectangular parallelepipeds made of graphite, aluminum, and titanium. The secondary radiation fields were recorded by a radiographic sensor. Using an X-ray source operating in a pulsed mode, images were obtained and profiles of the secondary radiation fields were formed. It is experimentally shown that the secondary radiation fields have a gradient structure and can be used to analyze the energy spectra of the radiation beams generating them. The method for reconstructing spectral distributions proposed in this work allows one to measure the energy spectra of photons using position-sensitive detectors and can be used in solving problems of diagnostics of pulsed high-intensity radiation beams.

Keywords: photon radiation, non-classical radiation spectrometers, maximum likelihood expectation maximization method.

А. С. Лелюхин, Д. А. Муслимов (Оренбургский государственный университет, Оренбург, Россия) E-mail: Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра. , Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.  

1. Balovnev A. V., Vizgalov I. V., Salahutdinov G. H. (2015). Diagnostics of anomalous electron-electron emission in the self-oscillating mode of a beam-plasma discharge using the method of filters and thermoluminescent detectors. Prikladnaya fizika, (1). [in Russian language]
2. Cao J., Jiang C. Y., Zhao Y. F. et al. (2016). A novel X-ray tube spectra reconstruction method based on transmission measurements. Nuclear Science and Techniques, Vol. 27, (2).
3. Cao J., Xiao R., Chen N. et al. (2015). Spectral reconstruction of the flash X-ray generated by Dragon-I LIA based on transmission measurements. Nuclear Science and Techniques, Vol. 26.
4. Kolevatov Yu. I., Semenov V. P., Trykov L. A. (1991). Spectrometry of neutrons and gamma radiation in radiation physics. Moscow: Energoatomizdat. [in Russian language]
5. Gallardo S., Ródenas J., Verdú G. (2019). Unfolding X-ray spectra using a flat panel detector. Determination of the accuracy of the method with the Monte Carlo method. Radiation Physics and Chemistry, Vol. 155, pp. 233 – 238.
6. Sidky E. Y., Yu L., Pan X. et al. (2005). A robust method of x-ray source spectrum estimation from transmission measurements: Demonstrated on computer simulated, scatter-free transmission data. Journal of applied physics, Vol. 97, (12).
7. Lelyuhin A. S., Piskareva T. I., Kornev E. A. (2018). Non-classical X-ray spectrometer based on a linear multichannel detector. Prikladnaya fizika, (2), pp. 90 – 96. [in Russian language]
8. Mainardi R. T., Barrea R. A. (1989). X-ray spectral determination by successive modifications of the beam intensity. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, Vol. 280, (2-3), pp. 387 – 391.
9. Endrizzi M., Delogu P., Oliva P. (2014). Application of an expectation maximization method to the reconstruction of X-ray-tube spectra from transmission data. Spectrochimica Acta Part B: Atomic Spectroscopy, Vol. 102, pp. 42 – 47.
10. Terebizh V. Yu. (2005). Introduction to the statistical theory of inverse problems. Moscow: Fizmatlit. [in Russian language]
11. Tarasko M. Z. (1983). Directional divergence minimum method in distribution search problems. Obninsk. [in Russian language]

This article  is available in electronic format (PDF).

The cost of a single article is 350 rubles. (including VAT 18%). After you place an order within a few days, you will receive following documents to your specified e-mail: account on payment and receipt to pay in the bank.

After depositing your payment on our bank account we send you file of the article by e-mail.

To order articles please copy the article doi:

10.14489/td.2020.12.pp.044-048

and fill out the  form  

 

 

 
Rambler's Top100 Яндекс цитирования