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http://dx.doi.org/10.1016/j.net.2020.06.033

Development of a neural network method for measuring the energy spectrum of a pulsed electron beam, based on Bremsstrahlung X-Ray  

Sohrabi, Mohsen (Faculty of Physics, University of Isfahan)
Ayoobian, Navid (Faculty of Physics, University of Isfahan)
Shirani, Babak (Faculty of Physics, University of Isfahan)
Publication Information
Nuclear Engineering and Technology / v.53, no.1, 2021 , pp. 266-272 More about this Journal
Abstract
In the pulsed electron beam generators, such as plasma focus devices and linear induction accelerators whose electron pulse width is in the range of nanosecond and less, as well as in cases where there is no direct access to electron beam, like runaway electrons in Tokamaks, measurement of the electron energy spectrum is a technical challenge. In such cases, the indirect measurement of the electron spectrum by using the bremsstrahlung radiation spectrum associated with it, is an appropriate solution. The problem with this method is that the matrix equation between the two spectrums is an ill-conditioned equation, which results in errors of the measured X-ray spectrum to be propagated with a large coefficient in the estimated electron spectrum. In this study, a method based on the neural network and the MCNP code is presented and evaluated to recover the electron spectrum from the X-ray generated by collision of the electron beam with a target. Multilayer perceptron network showed good accuracy in electron spectrum recovery, so that for the X-ray spectrum with errors of 3% and 10%, the network estimated the electron spectrum with an average standard error of 8% and 11%, on all of the energy intervals.
Keywords
Pulsed electron beam; Neural network; Multilayer perceptron; MCNP;
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1 N. Shamsian, B. Shirani bidabadi, H. Pirjamadi, Development of a radiographic method for measuring the discrete spectrum of the electron beam from a plasma focus device, Plasma Sci. Technol. 19 (2017), 075101.   DOI
2 B. Fathi-Vajargah, M. Moradi, Diagonal scaling of ill-conditioned matrixes by genetic algorithm, J. Appl. Math. Stat. Inf. 8 (2012) 49-53.
3 B. Fathi-Vajargah, M. Moradi, M. Kanafchian, Monte Carlo optimization for reducing the condition number of ill conditioned matrices, Adv. Comput. Math. Appl. (2012) 169-173.
4 S.M. Miremad, B. Shirani, Measurement of the effective energy of pulsed X-rays emitted from a Mather-type plasma focus device, Appl. Radiat. Isot. 125 (2017) 169-175.   DOI
5 R. Kwiatkowski, E. Skladnik-Sadowska, K. Malinowski, M.J. Sadowski, K. Czaus, J. Zebrowski, L. Karpinski, M. Paduch, M. Scholz, I.E. Garkusha, Measurements of electron and ion beams emitted from the PF-1000 device in the upstream and downstream direction, Nukleonika 56 (2011) 119-123.
6 M. Scholz, B. Bienkowska, V. Gribkov, R. Miklaszewski, Plasma focus as a source of intense radiation and plasma streams for technological applications, Acta Phys. Slovaca 54 (2004) 35-42.
7 C. Moreno, M. Venere, R. Barbuzza, M. Del Fresno, R. Ramos, H. Bruzzone, F. Gonzalez, A. Clausse, Industrial applications of plasma focus radiation, Braz. J. Phys. 32 (1) (2002) 20-25.   DOI
8 E. Ceccolini, F. Rocchi, D. Mostacci, M. Sumini, A. Tartari, A range-based method to calibrate a magnetic spectrometer measuring the energy spectrum of the backward electron beam of a plasma focus, Rev. Sci. Instrum. 82 (2011), 085103.   DOI
9 A. Patran, L. Tan, D. Stoenescu, M. Rafique, R. Rawat, S. Springham, T. Tan, P. Lee, M. Zakaullah, S. Lee, Spectral study of the electron beam emitted from a 3 kJ plasma focus, Plasma Sources Sci. Technol. 14 (2005) 549.   DOI
10 A. Patran, D. Stoenescu, R. Rawat, S. Springham, T. Tan, L. Tan, M. Rafique, P. Lee, S. Lee, A magnetic electron analyzer for plasma focus electron energy distribution studies, J. Fusion Energy 25 (2006) 57-66.   DOI
11 N. Neog, S. Mohanty, Study on electron beam emission from a low energy plasma focus device, Phys. Lett. 361 (2007) 377-381.   DOI
12 C.M. Johns, R. Lin, The derivation of parent electron spectra from bremsstrahlung hard X-ray spectra, Sol. Phys. 137 (1992) 121-140.   DOI
13 S.M. Miremad, B. Shirani, Improvement of the radiographic method for measurement of effective energy of pulsed X-ray emission from a PF device for different anode's insert materials, Appl. Radiat. Isot. 136 (2018) 21-26.   DOI
14 W. Surala, M.J. Sadowski, R. Kwiatkowski, L. Jakubowski, J. Zebrowski, Measurements of fast electron beams and soft X-ray emission from plasma-focus experiments, Nukleonika 61 (2016) 161-167.   DOI
15 A. Sharghi ido, M. Bonyadi, G. Etaati, M. Shahriari, Unfolding the neutron spectrum of a NE213 scintillator using artificial neural networks, Appl. Radiat. Isot. 67 (2009) 1912-1918.   DOI
16 W. Stygar, G. Gerdin, F. Venneri, J. Mandrekas, Particle beams generated by a 6-12.5 kJ dense plasma focus, Nucl. Fusion 22 (1982) 1161.   DOI
17 V. Raspa, C. Moreno, Radiographic method for measuring the continuum hard X-ray output spectrum of a Plasma Focus device, Phys. Lett. 373 (2009) 3659-3662.   DOI
18 A.C. Patran, Electron and Medium Energy X-Ray Emission from a Dense Plasma Focus, National Institute of Education, Nanyang Technological University. PhD., 2002.
19 E. Ceccolini, Development and Performance Assessment of a Plasma Focus Electron Beam Generator for Intra-operative Radiation Therapy, Bologna University. PhD., 2012.
20 H. Van Paassen, R. Vandre, R.S. White, X-ray spectra from dense plasma focus devices, Phys. Fluids 13 (1970) 2606-2612.   DOI
21 M. Sumini, L. Isolan, M. Cremonesi, C. Garibaldi, A Plasma Focus device as ultra-high dose rate pulsed radiation source. Part I: primary electron beam characterization, Radiat. Phys. Chem. 162 (2019) 1-11.   DOI