Analysis of Human Hair by the Laser-Induced Breakdown Spectroscopy

We experimentally studied the spectral characteristics of plasma generated on the surface of human hair under various focusing conditions (by the lenses with a focal length of 50, 100, 150 mm) by short (9 ns) laser pulses with an energy from 5 to 50 mJ in the regime of elemental composition analysis along the length of the samples. The minimal energetic levels of laser pulses were obtained. The optimal conditions for the registration of the emission lines of magnesium and calcium in the studied samples were determined. 

1. R. Chitturi, V. R. Baddam, L. Prasad, L. Prashanth, K. Kattapagari. J. Dr. NTR Univ. Health Sci., 4, N 2 (2015) 75—85

2. M. Bahreini, S. H. Tavassoli. J. Lasers Med. Sci., 3 (2012) 127—131

3. F. Musshoff, B. Madea. Anal. Bioanal. Chem., 388, N 7 (2007) 1475—1494

4. C. Krafft, S. B. Sobottka, G. Schackert, R. Salzer. Analyst, 129, N 10 (2004) 921—925

5. M. Tran, S. Sun, B. W. Smith, J. D. Winefordner. J. Anal. At. Spectrom., 16, N 6 (2001) 628—632

6. A. Miziolek, V. Palleschi, I. Schecter. Laser-Induced Breakdown Spectroscopy (LIBS) Fundamentals and Applications, Cambridge UK, Cambridge University Press (2006) 283—313

7. D. A. Cremers, L. J. Radziemski. Handbook of Laser-Induced Breakdown Spectroscopy, Chichester, Wiley & Sons (2006) 211—213

8. E. Tognoni, V. Palleschi, M. Corsi, G. Cristoforetti. Spectrochim. Acta B: At. Spectrosc., 57, N 7 (2002) 1115—1130

9. B. Busser, S. Moncayo, J. L. Coll, L. Sancey, V. Motto-Ros. Coord. Chem. Rev., 358 (2018) 70—79

10. J. Li, F. Chen, G. Huang, S. Zhang, W. Wang, Y. Tang, Y. Chu, J. Yao, L. Guo, F. Jiang. Front. Optoelectron., 14, N 3 (2020) 321—328

11. A. Marin Roldan, V. Dwivedi, J. Yravedra Sainz de los Terreros, P. Veis. Optik, 218 (2020)

12. W. Binggan, L. Yonghua, L. Hairong, Y. Jiangping, Y. Bixiong, L. Tao. Ecotoxic. Environ. Saf., 96, N 1 (2013) 118—123

13. http://www.knowledgedoor.com/2/elements_handbook/element_abundances_in_human_hair.html

14. H. Koichi, S. Rieko, K. Yuu, I Yusuke, I. Rie, N. Hiroyuki. J. Health Sci., 57, N 6 (2011) 472—487

15. T. Kamata, K. Sasaki, N. Shima, A. Miki, M. Katagi. Hyomen Kagaku, 38, N 8 (2017) 395—399

16. J. Moreda-Pineiro, E. Alonso-Rodriguez, P. Lopez-Mahia, S. Lorenzo, D. Prada-Rodriguez, A. Moreda-Pineiro, P. Bermejo-Barrera. Anal. Bioanal. Chem., 388, N 2 (2007) 441—449

17. V. A. Boumba, K. S. Ziavrou, T. Vougiouklakis. Int. J. Toxic., 25, N 3 (2006) 143—163

18. M. Yukawa, M. Suzuki-Yasumoto, S. Tanaka. Sci. Total Environ., 38 (1984) 41—54

19. R. J. Shamberger. Biol. Trace Elem., 87 (2002) 1—28

20. R. W. Phelps, T. W. Clarkson, T. G. Kershaw, B. Wheatley. Arch. Environ. Health, 35 (1980) 161—168

21. D. Weiss, B. Whitten, D. Leddy. Science, 178, N 4056 (1972) 69—70

22. T. Giovanoli-Jakubczak, G. G. Berg. Arch. Environ. Health, 28 (1974) 139—144

23. R. Gaudiuso, N. Melikechi, Z. Abdel-Salam, M. A. Harith, V. Palleschi, V. Motto-Ros, B. Busser. Spectrochim. Acta B: At. Spectrosc., 152 (2019) 123—148

24. E. Emara, H. Imam, M. Hassan, S. Elnaby. Talanta, 117 (2013) 176—183

25. V. K. Singh, A. K. Rai. Lasers Med. Sci., 26, N 5 (2011) 673—687

26. S. J. Rehse, H. Salimnia, A. W. Miziolek. J. Med. Eng. Technol., 36, N 2 (2012) 77—89