Evaluation of accuracy of the methods for determining spatial characteristics of electron radiation depth-dose distribution
Анотація
In the work, the numerical methods of determining the standard characteristics of the electron radiation depth-dose distribution by processing the measurement results are compared with the empirical formulas linking the same characteristics with the electrons energy. The comparison results allow authors to estimate the accuracy of methods used in radiation technologies to determine the characteristics of electron radiation energy.Завантаження
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Посилання
1. ICRU REPORT 35. Radiation dosimetry: electron beams with energies between 1 and 50 MeV.– 1984. – 160 c.
2. ASTM Standard E 1649 – 94, Practice for dosimetry in an e-beam facility for radiation processing at energies between 300 keV and 25 MeV
3. ISO/ASTM Standard 51649, Practice for dosimetry in an e-beam facility for radiation processing at energies between 300 keV and 25 MeV / Annual Book of ASTM Standards. – Vol. 12.02 (2005).
4. Lazurik V.T., Lazurik V.M., Popov G., Rogov Yu., Zimek Z. Information System and Software for Quality Control of Radiation Processing // IAEA: Collaborating Center for Radiation Processing and Industrial Dosimetry, Warsaw: Poland. – 2011. – 220 p.
5. Lazurik V.T., Pochynok A.V. Dosimetry of electrons on the base of computer modeling the depth-dose distribution of irradiation // Journal of Kharkiv University. Mathematical modeling. Information technologies series. – 2010. – No.925. – P.114 – 122.
6. Lisanti T.F. Calculating electron range values mathematically // Radiation Physics and Chemistry. – 2004. – Vol. 71. – Р. 581 –584.
7. Lazurik V.M., Tabata T., Lazurik V.T. A Database for Electron-Material Interactions // Radiation Physics and Chemistry. – 2001. – Vol.60. – P. 161-162.
8. Pochynok A.V., Lazurik V.T., Sarukhanyan G.E. The parametric method of the determination of electron energy on the data obtained by the method of a dosimetric wedge //Bulletin Kherson National Technical University. – 2012. – Vol. 2(45). – P.298 302.
9. Pochynok A.V., Lazurik V.T., Baiev O.U. Modeling the characteristics of uncertainty of the electron beam energy, obtained by the dosometric wedge method. //Bulletin of Kherson National Technical University. – 2010. – Vol. 3(39). – P.386 - 390.
10. V.T. Lazurik, V.M. Lazurik, G. Popov, Z. Zimek. Determination of electron beam parameters on radiation-technological facility for simulation of radiation processing //East European Journal of Physics. Vol.1. – 2014. – No.3. – P. 76-81.
11. Miller A. Polystyrene calorimeter for electron beam dose measurements // Radiation Physics and Chemistry. – 1993. – Vol.46. – Р. 1243–1246.
12. V.M. lazurik, V.T. lazurik, G. Popov , Z. Zimek. Energy characteristics in two-parametric model of electron beam. Bulletin of Kherson National Technical University. – 2015 –Vol. 3(54).– P.397 402
13. V.M. lazurik, V.T. lazurik, G. Popov , Z. Zimek. Two-parametric model of electron beam computational dosimetry for radiation processing. 13th Tihany Symposium on Radiation Chemistry. Balatonalmadi, Hungary. Abstract book. N053. 29.08.-03.09.2015.
2. ASTM Standard E 1649 – 94, Practice for dosimetry in an e-beam facility for radiation processing at energies between 300 keV and 25 MeV
3. ISO/ASTM Standard 51649, Practice for dosimetry in an e-beam facility for radiation processing at energies between 300 keV and 25 MeV / Annual Book of ASTM Standards. – Vol. 12.02 (2005).
4. Lazurik V.T., Lazurik V.M., Popov G., Rogov Yu., Zimek Z. Information System and Software for Quality Control of Radiation Processing // IAEA: Collaborating Center for Radiation Processing and Industrial Dosimetry, Warsaw: Poland. – 2011. – 220 p.
5. Lazurik V.T., Pochynok A.V. Dosimetry of electrons on the base of computer modeling the depth-dose distribution of irradiation // Journal of Kharkiv University. Mathematical modeling. Information technologies series. – 2010. – No.925. – P.114 – 122.
6. Lisanti T.F. Calculating electron range values mathematically // Radiation Physics and Chemistry. – 2004. – Vol. 71. – Р. 581 –584.
7. Lazurik V.M., Tabata T., Lazurik V.T. A Database for Electron-Material Interactions // Radiation Physics and Chemistry. – 2001. – Vol.60. – P. 161-162.
8. Pochynok A.V., Lazurik V.T., Sarukhanyan G.E. The parametric method of the determination of electron energy on the data obtained by the method of a dosimetric wedge //Bulletin Kherson National Technical University. – 2012. – Vol. 2(45). – P.298 302.
9. Pochynok A.V., Lazurik V.T., Baiev O.U. Modeling the characteristics of uncertainty of the electron beam energy, obtained by the dosometric wedge method. //Bulletin of Kherson National Technical University. – 2010. – Vol. 3(39). – P.386 - 390.
10. V.T. Lazurik, V.M. Lazurik, G. Popov, Z. Zimek. Determination of electron beam parameters on radiation-technological facility for simulation of radiation processing //East European Journal of Physics. Vol.1. – 2014. – No.3. – P. 76-81.
11. Miller A. Polystyrene calorimeter for electron beam dose measurements // Radiation Physics and Chemistry. – 1993. – Vol.46. – Р. 1243–1246.
12. V.M. lazurik, V.T. lazurik, G. Popov , Z. Zimek. Energy characteristics in two-parametric model of electron beam. Bulletin of Kherson National Technical University. – 2015 –Vol. 3(54).– P.397 402
13. V.M. lazurik, V.T. lazurik, G. Popov , Z. Zimek. Two-parametric model of electron beam computational dosimetry for radiation processing. 13th Tihany Symposium on Radiation Chemistry. Balatonalmadi, Hungary. Abstract book. N053. 29.08.-03.09.2015.
Опубліковано
2015-11-30
Як цитувати
Lazurik, V., Popov, G., Salah, S., & Zimek, Z. (2015). Evaluation of accuracy of the methods for determining spatial characteristics of electron radiation depth-dose distribution. Вісник Харківського національного університету імені В.Н. Каразіна, серія «Математичне моделювання. Інформаційні технології. Автоматизовані системи управління», 28, 126-139. вилучено із https://periodicals.karazin.ua/mia/article/view/5478
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