Further Investigation of α+12C and α+16O Elastic Scattering
The current work aims to study the rainbow like-structure observed in the elastic scattering of alpha particles on both 12C and 16O nuclei. We reanalyzed the experimental elastic scattering angular distributions data for α+12C and α+16O nuclear systems at different energies using both optical model and double folding potential of different interaction models such as: CDM3Y1, DDM3Y1, CDM3Y6 and BDM3Y1. Potential created by BDM3Y1 interaction model has the shallowest depth which reflects the necessity to use higher renormalization factor (Nr). Both optical model and double folding potential of different interaction models fairly reproduce the experimental data.
[1] D. A. Goldberg, S. M. Smith and G. F. Burdzik, Phys. Rev. C 10 (1974) 1362.
[2] R. M. DeVries, D. A. Goldberg, J. W. Watson, M. S. Zisman, and J. G. Cramer, Phys. Rev. Lett. 39 (1977) 450.
[3] P. Schwandt, S. Kailas, W. W. Jacobs, M. D. Kaitchuck, W. Ploughe, and P. P. Singh, Phys. Rev. C 21 (1980) 1656.
[4] A. A. Ogloblin, Yu. A. Glukhov, W. H. Trzaska, A. S. Dem’yanova, S. A. Goncharov, R. Julin, S. V. Klebnikov, M. Mutterer, M. V. Rozhkov, V. P. Rudakov, G. P. Tiorin, Dao T. Khoa, and G. R. Satchler, Phys. Rev. C 62 (2000) 044601.
[5] M. P. Nicoli, F. Haas, R. M. Freeman, S. Szilner, Z. Basrak, A. Morsad, G. R. Satchler, and M. E. Brandan, Phys. Rev. C 61 (2000) 034609.
[6] Yu. A. Glukhov, S. A. Goncharov, A. S. Dem’yanova, A. A. Ogloblin, M. V. Rozhkov, V. P. Rudakov, V. Trashka, J. IZV 65 (2001) 647.
[7] M. Buenerd, P. Martin, R. Bertholet, C. Guet, M. Maurel, J. Mougey, H. Nifenecker, J. Pinston, P. Perrin, F. Schussler, J. Jullen, J. P. Bondorf, L. Carlen, H. Å. Gustafsson, B. Jakobsson, T. Johansson, P. Kristiansson, O. B. Nielsen, A. Oskarsson, I. Otterlund, H. Ryde, B. Schröder, and G. Tibell, Phys. Rev. C 26 (1982) 1299.
[8] S. Kubono, K. Morita, M.H. Tanaka, M. Sugitani, H. Utsunomiya, H. Yonehara, M.-K. Tanaka, S. Shimoura, E. Takada, M. Fukuda, K. Takimoto, Phys. Lett. B. 127 (1983) 19.
[9] H. G. Bohlen, X. S. Chen, J. G. Cramer, P. Fröbrich, B. Gebauer, H. Lettau, A. Miczaika, W. von Oertzen, R. Ulrich, T. Wilpert, Z. Phys. A. 322 (1985) 241.
[10] A. J. Cole, W. D. M. Rae, M. E. Brandan, A. Dacal, B. G. Harvey, R. Legrain, M. J. Murphy, R. G. Stokstad, Phys. Rev. Lett. 47 (1981) 1705.
[11] M. Buenerd, A. Lounis, J. Chauvin, D. Lebrun, P. Martin, G. Duhamel, J.C. Gondrand, P. De Saintignon, Nucl. Phys. A. 424 (1984) 313.
[12] J.Y. Hostachy, M. Buenerd, J. Chauvin, D. Lebrun, Ph. Martin, B. Bonin, G. Bruge, J.C. Lugol, L. Papineau, P. Roussel, J. Arvieux, C. Cerruti, Phys. Lett. B. 184 (1987) 139.
[13] C.C. Sahm, T. Murakami, J.G. Cramer, A.J. Lazzarini, D.D. Leach, D.R. Tieger, R.A. Loveman, W.G. Lynch, M.B. Tsang, J. Van der, Phys. Rev. C 34 (1986) 2165.
[14] M. E. Brandan, Phys. Rev. Lett. 60 (1988) 784.
[15] M. El-Azab Farid, Z. M. M. Mahmoud, and G. S. Hassan, Phys. Rev. C 64 (2001) 014310.
[16] Dao T. Khoa, Phys. Rev. C 63 (2001) 034007.
[17] Sh. Hamada, Y. Hirabayashi, N. Burtebayev, S Ohkubo, Phys. Rev. C 87, 024311 (2013).
[18] Y. Hirabayashi and S. Ohkubo, Phys. Rev. C 88 014314 (2013).
[19] D. A. Goldberg and S. M. Smith, Phys. Rev. Lett. 33 (1974) 715.
[20] F. Michel, J. Albinski, P. Belery, Th. Delbar, Gh. Grégoire, B. Tasiaux, and G. Reidemeister, Phys. Rev. C 28(1983) 1904.
[21] H. Abele, H. J. Hauser, A. Körber, W. Leitner, R. Neu, H. Plappert, T. Rohwer, G. Staudt, M. Strasser, S. Weite, and M. Walz, Z. Phys. A 326, 373 (1987).
[22] F. Michel, Phys. Lett. 60B (1976) 229.
[23] Z. Majka, H. J. Gils, and H. Rebel, Phys. Rev. C 25 (1982) 2996.
[24] M. El-Azab Farid, J. Phys. G 16 (1990) 461.
[25] S. A. E. Khallaf, A. M. Amry, and S. R. Mokhtar, Phys. Rev.C 56 (1997) 2093.
[26] I. I. Gontchar and M. V. Chushnyakova, Comput. Phys. Commun. 181 (2010) 168.
[27] Dao T. Khoa, G.R. Satchler, W. von Oertzen, Phys. Rev. C 56 (1997) 954.
[28] S. Qing-biao, F. Da-chun and Z. Yi-Zhong, Phys. Rev. C 43(1991) 2773.
[29] G.R. Satchler, W.G. Love, Phys. Rep. 55 (1979) 183.
[30] I. J. Thompson, Comput. Phys. Rep. 7 (1988) 167.
[31] B. Tatischeff, I. Brissauud, Nucl. Phys. A. 155 (1970) 89.
[32] S. Wiktor, C. Mayer-Böricke, A. Kiss, M. Rogge, P. Turek, H. Dabrowski, Acta Phys. Pol. B 12 (1981) 491.
[33] G. Hauser, R. Löhken, H. Rebel, G. Schatz, G.W. Schweimer, J. Specht, Nucl. Phys. A. 128 (1969) 81.
[34] M. Yasue, T. Tanabe, F. Soga, J. Kokame, F. Shimokoshi, J. Kasagi, Y. Toba, Y. Kadota, T. Ohsawa, K. Furuno, Nucl. Phys. A. 394 (1983) 14.
[35] S. M. Smith, G. Tibell, A. A. Cowley, D. A. Goldberg, H. G. Pugh, W. Reichart, N.S. Wall, Nucl. Phys. A. 207 (1973) 273.
[36] M. Reed thesis, Lawrence Berkeley National Laboratory, Berkeley, CA, USA (1968).
[1] D. A. Goldberg, S. M. Smith and G. F. Burdzik, Phys. Rev. C 10 (1974) 1362.
[2] R. M. DeVries, D. A. Goldberg, J. W. Watson, M. S. Zisman, and J. G. Cramer, Phys. Rev. Lett. 39 (1977) 450.
[3] P. Schwandt, S. Kailas, W. W. Jacobs, M. D. Kaitchuck, W. Ploughe, and P. P. Singh, Phys. Rev. C 21 (1980) 1656.
[4] A. A. Ogloblin, Yu. A. Glukhov, W. H. Trzaska, A. S. Dem’yanova, S. A. Goncharov, R. Julin, S. V. Klebnikov, M. Mutterer, M. V. Rozhkov, V. P. Rudakov, G. P. Tiorin, Dao T. Khoa, and G. R. Satchler, Phys. Rev. C 62 (2000) 044601.
[5] M. P. Nicoli, F. Haas, R. M. Freeman, S. Szilner, Z. Basrak, A. Morsad, G. R. Satchler, and M. E. Brandan, Phys. Rev. C 61 (2000) 034609.
[6] Yu. A. Glukhov, S. A. Goncharov, A. S. Dem’yanova, A. A. Ogloblin, M. V. Rozhkov, V. P. Rudakov, V. Trashka, J. IZV 65 (2001) 647.
[7] M. Buenerd, P. Martin, R. Bertholet, C. Guet, M. Maurel, J. Mougey, H. Nifenecker, J. Pinston, P. Perrin, F. Schussler, J. Jullen, J. P. Bondorf, L. Carlen, H. Å. Gustafsson, B. Jakobsson, T. Johansson, P. Kristiansson, O. B. Nielsen, A. Oskarsson, I. Otterlund, H. Ryde, B. Schröder, and G. Tibell, Phys. Rev. C 26 (1982) 1299.
[8] S. Kubono, K. Morita, M.H. Tanaka, M. Sugitani, H. Utsunomiya, H. Yonehara, M.-K. Tanaka, S. Shimoura, E. Takada, M. Fukuda, K. Takimoto, Phys. Lett. B. 127 (1983) 19.
[9] H. G. Bohlen, X. S. Chen, J. G. Cramer, P. Fröbrich, B. Gebauer, H. Lettau, A. Miczaika, W. von Oertzen, R. Ulrich, T. Wilpert, Z. Phys. A. 322 (1985) 241.
[10] A. J. Cole, W. D. M. Rae, M. E. Brandan, A. Dacal, B. G. Harvey, R. Legrain, M. J. Murphy, R. G. Stokstad, Phys. Rev. Lett. 47 (1981) 1705.
[11] M. Buenerd, A. Lounis, J. Chauvin, D. Lebrun, P. Martin, G. Duhamel, J.C. Gondrand, P. De Saintignon, Nucl. Phys. A. 424 (1984) 313.
[12] J.Y. Hostachy, M. Buenerd, J. Chauvin, D. Lebrun, Ph. Martin, B. Bonin, G. Bruge, J.C. Lugol, L. Papineau, P. Roussel, J. Arvieux, C. Cerruti, Phys. Lett. B. 184 (1987) 139.
[13] C.C. Sahm, T. Murakami, J.G. Cramer, A.J. Lazzarini, D.D. Leach, D.R. Tieger, R.A. Loveman, W.G. Lynch, M.B. Tsang, J. Van der, Phys. Rev. C 34 (1986) 2165.
[14] M. E. Brandan, Phys. Rev. Lett. 60 (1988) 784.
[15] M. El-Azab Farid, Z. M. M. Mahmoud, and G. S. Hassan, Phys. Rev. C 64 (2001) 014310.
[16] Dao T. Khoa, Phys. Rev. C 63 (2001) 034007.
[17] Sh. Hamada, Y. Hirabayashi, N. Burtebayev, S Ohkubo, Phys. Rev. C 87, 024311 (2013).
[18] Y. Hirabayashi and S. Ohkubo, Phys. Rev. C 88 014314 (2013).
[19] D. A. Goldberg and S. M. Smith, Phys. Rev. Lett. 33 (1974) 715.
[20] F. Michel, J. Albinski, P. Belery, Th. Delbar, Gh. Grégoire, B. Tasiaux, and G. Reidemeister, Phys. Rev. C 28(1983) 1904.
[21] H. Abele, H. J. Hauser, A. Körber, W. Leitner, R. Neu, H. Plappert, T. Rohwer, G. Staudt, M. Strasser, S. Weite, and M. Walz, Z. Phys. A 326, 373 (1987).
[22] F. Michel, Phys. Lett. 60B (1976) 229.
[23] Z. Majka, H. J. Gils, and H. Rebel, Phys. Rev. C 25 (1982) 2996.
[24] M. El-Azab Farid, J. Phys. G 16 (1990) 461.
[25] S. A. E. Khallaf, A. M. Amry, and S. R. Mokhtar, Phys. Rev.C 56 (1997) 2093.
[26] I. I. Gontchar and M. V. Chushnyakova, Comput. Phys. Commun. 181 (2010) 168.
[27] Dao T. Khoa, G.R. Satchler, W. von Oertzen, Phys. Rev. C 56 (1997) 954.
[28] S. Qing-biao, F. Da-chun and Z. Yi-Zhong, Phys. Rev. C 43(1991) 2773.
[29] G.R. Satchler, W.G. Love, Phys. Rep. 55 (1979) 183.
[30] I. J. Thompson, Comput. Phys. Rep. 7 (1988) 167.
[31] B. Tatischeff, I. Brissauud, Nucl. Phys. A. 155 (1970) 89.
[32] S. Wiktor, C. Mayer-Böricke, A. Kiss, M. Rogge, P. Turek, H. Dabrowski, Acta Phys. Pol. B 12 (1981) 491.
[33] G. Hauser, R. Löhken, H. Rebel, G. Schatz, G.W. Schweimer, J. Specht, Nucl. Phys. A. 128 (1969) 81.
[34] M. Yasue, T. Tanabe, F. Soga, J. Kokame, F. Shimokoshi, J. Kasagi, Y. Toba, Y. Kadota, T. Ohsawa, K. Furuno, Nucl. Phys. A. 394 (1983) 14.
[35] S. M. Smith, G. Tibell, A. A. Cowley, D. A. Goldberg, H. G. Pugh, W. Reichart, N.S. Wall, Nucl. Phys. A. 207 (1973) 273.
[36] M. Reed thesis, Lawrence Berkeley National Laboratory, Berkeley, CA, USA (1968).
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:74445", author = "Sh. Hamada", title = "Further Investigation of α+12C and α+16O Elastic Scattering", abstract = "The current work aims to study the rainbow like-structure observed in the elastic scattering of alpha particles on both 12C and 16O nuclei. We reanalyzed the experimental elastic scattering angular distributions data for α+12C and α+16O nuclear systems at different energies using both optical model and double folding potential of different interaction models such as: CDM3Y1, DDM3Y1, CDM3Y6 and BDM3Y1. Potential created by BDM3Y1 interaction model has the shallowest depth which reflects the necessity to use higher renormalization factor (Nr). Both optical model and double folding potential of different interaction models fairly reproduce the experimental data.", keywords = "Nuclear rainbow, elastic scattering, optical model, double folding, density distribution.", volume = "10", number = "12", pages = "1461-11", }
