The source of X-rays and high-charged ions based on moderate power vacuum discharge with laser triggering

1. Korop, E. D., Meyerowitz, B. E., Sidel’nikov, J. V., & Sukhorukov, S. T. (1979). Micropinches in high-current diode. Sov. Phys. Usp., 129(1), 87–112.10.3367/UFNr.0129.197909c.0087Search in Google Scholar

2. Georgescu, N., Serbanescu, C. G., & Sandolache, G. (2001). Reproducibility conditions for the pulsed X-ray emission in a vacuum spark discharge. Nukleonika, 46(Suppl. 1), 17–20.Search in Google Scholar

3. Korobkin, Yu. V., Paperny, V. L., Romanov, I. V., Rupasov, A. A., & Shikanov, A. S. (2008). Micropinches in laser induced moderate power vacuum discharge. Plasma Phys. Control. Fusion, 50, 1–14, DOI: 10.1088/0741-3335/50/6/065002.10.1088/0741-3335/50/6/065002Search in Google Scholar

4. Korobkin, Yu. V., Romanov, I. V., Rupasov, A. A., & Shikanov, A. S. (2005). Vacuum discharge instability in laser initiation of the cathode spot. J. Tech. Phys., 75(9), 34–39.10.1134/1.2051451Search in Google Scholar

5. Baechler, S., Monnin, P., Aroua, A., Valley, J. F., Perrier, M., Trueb, P., & Verdun, F. R. (2010). Exposure in dental radiology: A comparison between intra-oral, panoramic and tomographic examinations. Radiat. Prot. Dosim., 139(1/3), 303–305.Search in Google Scholar

6. Bashutin, O. A., Alkhimova, M. A., Vovchenko, E. D., Dodulad, E. I., Savelov, A. S., & Sarancev, S. A. (2013). Effect of electrode system on the radiative characteristics of the vacuum spark. Plasma Phys., 39(11), 1006–1016.Search in Google Scholar

7. Basov, N. G., Zaharenko, Yu. A., Rupasov, A. A., Slizkov, V. G., & Shikanov, A. S. (1989). The diagnostics of the dense plasma (pp. 127–130). Moscow: Nauka.Search in Google Scholar

8. Averin, M. S., Bajkov, A. Y., Bashutin, O. A., Vovchenko, E. D., & Savelov, A. S. (2006). Estimates of the electron temperature of the plasma discharge to weaken micropinch X-ray flux in the emulsion. Instrum. Exp. Tech., 2(1), 5.Search in Google Scholar

9. Dolgov, A. N., Savelov, A. S., & Salakhutdinov, G. Kh. (2008). Application of a spectrometer complex of equipment for x-ray diagnostics of plasma of pulse installations. Prikladnaya Fizika (Applied Physics), 5, 35–40.Search in Google Scholar

10. Bykovskii, Y. A., & Nevolin, V. N. (1985). Laser mass spectrometry. Moscow: Energoatomizdat.Search in Google Scholar

11. Basov, N. G., Zakharenkov, Y. A., Rupasov, A. A., Sklizkov, G. V., & Shikanov, A. C. (1989). Diagnosis of a dense plasma. Moscow: Nauka.Search in Google Scholar

12. Romanov, I. V., Paperny, V. L., Korobkin, V., Kiselev, N. G., Rusape, A. A., & Shikanov, A. S. (2013). Effect of laser pulse parameters on characteristic source of multiply charged ions of metals based on laser-induced spark average power. Lett. Tech. Phys., 39(8), 62–70.Search in Google Scholar

13. Bufetov, I. A., Bufetova, G. A., Kravtsov, S. B., Fyodorov, V. B., & Fomin, V. K. (1995). Heating of the plasma on a metal target by nanosecond pulses of the first, second and fourth harmonics Nd-laser. Quantum Electron., 25(8), 794–798.10.1070/QE1995v025n08ABEH000470Search in Google Scholar

14. http://physics.nist.gov/PhysRefData/ASD/levels_form.html.Search in Google Scholar