Обнаружение изотопов водорода с помощью лазерно-искровой эмиссионной спектроскопии

Проанализированы спектроскопические методы обнаружения изотопов водорода в материалах термоядерных реакторов, поскольку их присутствие может оказывать влияние на деградацию материала и срок его службы. Лазерно-искровая эмиссионная спектроскопия рассмотрена как эффективный, надежный и быстрый метод оптической эмиссии.

1. M. Trtica, M. Kuzmanovic, J. Savovic, D. Rankovic, Appl. Surf. Sci., 572, 151424 (2022).

2. M. Trtica, J. Savovic, M. Kuzmanovic, D. Rankovic, Proc. X Int. Conf. “Plasma Physics and Plasma Technology”, September 12–16, 2022, Minsk, Belarus, 173–176 (2022).

3. C. N. Taylor, J. Nuclear Mater., 558, 153396 (2022).

4. R. Gonzalez-Arrabal, A. Rivera, J. M. Perlado, Matter. Radiat. Extremes, 5, 055201 (2020).

5. A. K. Suri, N. Krishnamurthy, I. S. Batra, J. Phys: Conf. Ser., 208, 012001 (2010).

6. J. M. Perlado, J. Sanz, J. Alvarez, D. Cereceda, et al., Proc. SPIE, 8080, 80801Z(1–10) (2011).

7. L. Gao, A. Manhard, W. Jacob, von U. Toussaint, M. Balden, K. Schmid, Nuclear Fusion, 59, No. 5, 056023 (2019).

8. M. Victoria, N. Baluc, P. Spatig, Nucl. Fusion, 41, No. 8, 1047–1053 (2001).

9. S. Sahin, J. Ther. Eng., 5, No. 2, 46–57 (2019).

10. J. Chene, F. Martin, Phil. Trans. R. Soc. A, 375, 20160406 (2017).

11. R. H. Jones, J. Nuclear Mater., 141-143, 468–475 (1986).

12. J. B. Condon, T. Schober, J. Nuclear Mater., 207, 1–24 (1993).

13. M. K. Gupta, A. Priyadarshi, N. Manwal, Z. Khan, “Techniques to Measure Hydrogen Content in SS 304L”. Technical Report IPR/TR-377/2016. IPR Library, India (2016).

14. M. R. Leahy-Hoppa, J. Miragliotta, R. Osiander, J. Burnett, Y. Dikmelik, C. McEnnis, J. B. Spicer, Sensors, 10, No. 5, 4342–4372 (2010).

15. V. K. Singh, A. K. Rai, Laser Med. Sci., 26, No. 5, 673–687 (2011).

16. D. W. Hahn, N. Omenetto, Appl. Spectrosc., 64, No. 12, 335–366 (2010).

17. D. A. Cremers, L. J. Radziemski, Handbook of Laser-Induced Breakdown Spectroscopy, 2nd ed., John Wiley and Sons, Ltd. New Delhi (2013).

18. M. S. Trtica, J. Savovic, M. Stoiljkovic, M. Kuzmanovic, M. Momcilovic, J. Ciganovic, S. Zivkovic, Proc. SPIE, 9810, 981010(1–11) (2015).

19. S. Legnaioli, B. Campanella, F. Poggialini, S. Pagnotta, M. A. Harith, Z. A. Abdel-Salam, V. Palleschi, Anal. Methods, 12, 1014–1029 (2020).

20. J. Oelmann, E. Wust, G. Sergienko, S. Brezinsek, Phys. Scr., 96, No. 12, 124064 (2021).

21. D. Zhao, C. Li, Z. Hu, C. Feng, Q. Xiao, R. Hai, P. Liu, L. Sun, D. Wu, C. Fu, J. Liu, N. Farid, F. Ding, G. N. Luo, L. Wang, H. Ding, Rev. Sci. Instrum., 89, No. 7, 073501 (2018).

22. N. Ashikawa, D. Zhao, C. Li, H. Ding, LHD Exp. Group, Proc. of A3 Foresight Program Seminar on Critical Physics Issues Specific to Steady State Sustainment of High-Performance Plasmas 2015. Available online: https://inis.iaea.org/collection/NCLCollectionStore/_Public/49/089/49089674.pdf?r=1

23. I. Jogi, J. Ristkok, J. Raud, J. Butikova, K. Mizohata, P. Paris, Fus. Eng. Design, 179, 113131 (2022).

24. H. J. vander Meiden, S. Almaviva, J. Butikova, V. Dwivedi, P. Gasior, W. Gromelski, A. Hakola, X. Jiang, I. Jõgi, J. Karhunen, M. Kubkowska, M. Laan, G. Maddaluno, A. Marín-Roldán, P. Paris, K. Piip, M. Pisarcík, G. Sergienko, M. Veis, P. Veis, S. Brezinsek, Nuclear Fusion, 61, No. 12, 125001 (2021).

25. R. Fantoni, S. Almaviva, L. Caneve, F. Colao, G. Maddaluno, P. Gasior, M. Kubkowska, Spectrochim. Acta B, 129, 8–13 (2017).

26. S. Almaviva, L. Caneve, F. Colao, G. Maddaluno, Fus. Eng. Design B, 146, 2087–2091 (2019).

27. D. W. Kneff, W. E. Nagel, H. Pearlman, V. J. Schaubert, A Document Review to Characterize Atomic International SNAP Fuels Shipped to INEL 1966-1973. Report INEL-95/0131 UC-510 (1995).

28. K. H. Kurniawan, T. J. Lie, N. Idris, T. Kobayashi, T. Maruyama, H. Suyanto, K. Kagawa, M. OnTjia, J. Appl. Phys., 96, No. 3, 1301–1309 (2004).

29. A. C. Fraker, Corrosion of Zircaloy Spent Fuel Cladding in a Repository, National Institute of Standards and Technology, USA (1989).

30. S. Suman, Nucl. Eng. Tech., 53, No. 2, 474–483 (2021).

31. M. Pardede, I. Kamadi, R. Hedwik, I. Tanra et al., Nat. Sci. Rep., 11, 21999 (2021).

32. E. J. Kautz, A. Devaraj, D. J. Senor, S. S. Harilal, Opt. Express, 29, No. 4, 4936–4946 (2021).

33. A. I. Whitehouse, Spectrosc. Eur., 18, No. 2, 14–21 (2006).

34. M. Momčilović, S. Živković, M. Kuzmanović, J. Ciganović, D. Ranković, M. Trtica, J. Savović, Plasma Chem. Plasma Proc., 39, No. 4, 985–1000 (2019).

35. M. Kuzmanović, D. Ranković, M. Trtica, J. Ciganović, J. Petrović, J. Savović, Spectrochim. Acta B, 157, 37–46 (2019).

36. M. Momcilovic, M. Kuzmanovic, D. Rankovic, J. Ciganovic, M. Stoiljkovic, J. Savovic, M. Trtica, Appl. Spectrosc., 69, No. 4, 419–429 (2015).

37. W. O. Siew, K. H. Wong, S. S. Yap, T. Y. Tou, IEEE Trans. Plasma Sci., 33, No. 1, 176–182 (2005).

38. A. N. Panchenko, M. A. Shulepov, A. E. Tel'minov, L. A. Zakharov, A. A. Paletsky, N. M. Bulgakova, J. Phys. D: Appl. Phys., 44, No. 38, 385201 (2011).

39. Y. Yu, L. B. Guo, Z. Q. Hao, X. Y. Li, M. Shen, Q. D. Zeng, K. H. Li, X. Y. Zeng, Y. F. Luand, Z. Ren, Opt. Express, 22, No. 4, 3895–3901 (2014).

40. M. Schwickert, E. Carpene, K. P. Leib, M. Uhrmacher, P. Schaaf, Appl. Phys. Lett., 84, No. 25, 5231–5233 (2004).

41. V. S. Burakov, V. V. Kiris, M. I. Nedelko, A. A. Nevar, N. V. Tarasenko, Proc. XII Symp. of Belarus and Serbia on Phys. and Diagnostic of Lab. and Astrophys. Plasmas, August 27–31, 2018, Belgrade, 5–8 (2018).