views: 1316
Readers community rating: votes 0
1. Vainionpaa J. H., Gough R., Hoff M. et al. Microwave Ion Source and Beam Injection for an Accelerator-Driven Neutron Source // Proc. Particle Accelerator Conf. Albuquerque: IEEE, 2007. 9889878.
2. Vainionpaa J. H., Allan X. C., Melvin A.P et al. Development of High Flux Thermal Neutron Generator for Neutron Activation Analysis // Nucl. Instr. Meth. B. 2015. V. 350. P. 88.
3. Bitulev A. A., Rumyantsev G. S., Churin S. V., Schitov N. N. Problemy povysheniya stabil'nosti raboty nejtron- nykh generatorov na vakuumnykh nejtronnykh trubkakh // Uspekhi prikl. fiziki. 2014. T. 2. № 3. S. 303.
4. Bogolyubov E. P., Vasin V. S. Gazonapolnennaya nejtronnaya trubka s istochnikom penninga. Patent na izobretenie № 2372755. Kl. MPK-H05H3/06 10.11.2009.
5. Ginzburg V. L., Rukhadze A. A. Volny v magnitoaktivnoj plazme. M.: Nauka, 1975. 254 s.
6. Waldmann O., Ludewigt B. A Permanent-Magnet Microwave Ion Source for a Compact High-Yield Neutron Generator // AIP Conf. Proc. 2010. V. 1336. P. 479.
7. Matveyev A. A., Silakov V. P. Kinetic Processes in a Highly-ionized Non-equilibrium Plasma // Plasma Sources Sci. Technol. 1995. V. 4. P. 606.
8. Silakov V. P., Matveyev A. A., Chebotarev A. V., Otorbaev D. K. Non-equilibrium Properties of a Flowing Hydrogen Cascaded Arc Plasma: Kinetic Modeling // J. Phys. D: Appl. Phys. 1996. V. 29. P. 2111.
9. Storozhev D. A. Chislennoe modelirovanie kinetiki ionizatsii i dissotsiatsii vodoroda v plazme razryada Penninga v priblizhenii LTR // Fiziko-khimicheskaya kinetika v gazovoj dinamike. 2014. T. 15. Vyp. 3.
10. Storozhev D. A., Kuratov S. E. Numerical Simulation of the Kinetics of Dissociation and Ionization of Molecular Hydrogen in the Penning Discharge Plasma with the Use of the Reduced Kinetic Model // J. Phys.: Conf. Ser. 2017. V. 815. № 1. 012002.
11. Shakhatov V. A., Lebedev Yu. A., Lacoste A., Bechu S. Kinetika vozbuzhdeniya ehlektronnykh sostoyanij molekul vodoroda v neravnovesnykh razryadakh. Osnovnoe ehlektronnoe sostoyanie // TVT. 2015. T. 53. № 4. S. 601.
12. Shakhatov V. A., Lebedev Yu. A., Lacoste A., Bechu S. Kinetika ehlektronnykh sostoyanij molekul vodoroda v neravnovesnykh razryadakh. Singletnye sostoyaniya // TVT. 2016. T. 54. № 1. S. 120.
13. Shakhatov V. A., Lebedev Yu. A., Lacoste A., Bechu S. Kinetika zaseleniya tripletnykh sostoyanij molekuly vodoroda v EhTsR-razryade // Uspekhi prikl. fiziki. 2017. T. 5. № 3. S. 24 9.
14. Celiberto R., Janev R. K., Laricchiuta A. et al. Cross Section Data for Electron-Impact Inelastic Processes of Vibrationally Excited Molecules of Hydrogen and its Isotopes // Atom. Data Nucl. Data Tables. 2001. V. 77. P. 161.
15. Abdellahi E. L., Ghazaly M. O., Jureta J., Urbain X., Defrance P. Total Cross Sections and Kinetic Energy Release for the Electron Impact Dissociation of H+2 and D+2 // J. Phys. B: At. Mol. Opt. Phys. 2004. V. 37. P. 2467.
16. Peart B., Dolder K. T. Measurements of Cross Sections for the Dissociative Recombination of D2+ Ions // J. Phys. B: Atom. Molec. Phys. 1973. V. 6. P. 359.
17. Stepanov D. S., Chebotarev A. V., Shkolnikov E. Ya. Electromagnetic Field in the Resonator of Neutron Generator’s Hydrogen Ion Source // Proc. Int. Conf. on Actual Problems of Electron Devices Engineering. Saratov: IEEE Xplore, 2016. V. 2. 7879076.
18. Landau L. D. Fizicheskaya kinetika. M.: Fizmatlit, 2007. 535 s.
19. Zhizhong Song, Shixiang Peng, Jinxiang Yu et al. Minipermanent Magnet High-current Microwave Ion Source // Rev. Sci. Instrum. 2006. V. 77. 03A305.
20. Kwan J. W., Gough R., Keller R. et al. A 2.45 GHz High Current Ion Source for Neutron Production // High Energy Phys. Nucl. Phys. 2007. V. 31. P. 232.