by Win, Kalayar, Fujita, Yoshitaka, Yeeoo, Yee and Fujita, Hiro
Abstract:
The Gamow-Teller (GT) transition is a powerful tool to study nuclear structure because of its simple form of the operator $\sigma$$\tau$. The structure of 26Al is studied through Gamow-Teller transitions using nuclear charge-exchange reaction. The reaction 26 Mg( 3 He,t) 26 Al was performed at an incident energy of 140 MeV/nucleon and scattering angle at and near 0˚. The energy resolution of $\Delta$E = 22 keV allowed us to study many discrete states. Most of the prominent states are suggested that they are excited with $\Delta$L = 0 GT transitions. The GT states were studied up to 18.5 MeV. For the extraction of the B(GT) value, the proportionality between cross section and B(GT) was used. The standard B(GT) values were obtained from the 26 Si beta decay, where the mirror symmetry of B(GT) was obtained. The T = 2 GT states are expected in the region E x ≥ 13.5 MeV. By comparing with the results of 26 Mg(t, 3 He) 26 Na reactions, the isospin symmetry of T = 2 GT states is discussed. Due to the high-energy resolution, the decay widths $\Gamma$ for the states in the E x > 9 MeV region could be studied. The narrow width of the T = 2 states at 13.592 MeV is explained in terms of isospin selection rules.
Reference:
Win, Kalayar, Fujita, Yoshitaka, Yeeoo, Yee and Fujita, Hiro, "Analysis of high energy resolution data of $^{26}$Mg( $^3$He,t)$^{26}$Al reaction", In EPJ Web of Conferences (Yang, A., Wang, W.Y., Ng, S.C.C., Chan, A.H., Oh, C.H., Phua, K.K., eds.), pp. 08003, 2019.
Bibtex Entry:
@inproceedings{Win2019,
abstract = {The Gamow-Teller (GT) transition is a powerful tool to study nuclear structure because of its simple form of the operator $\sigma$$\tau$. The structure of 26Al is studied through Gamow-Teller transitions using nuclear charge-exchange reaction. The reaction 26 Mg( 3 He,t) 26 Al was performed at an incident energy of 140 MeV/nucleon and scattering angle at and near 0˚. The energy resolution of $\Delta$E = 22 keV allowed us to study many discrete states. Most of the prominent states are suggested that they are excited with $\Delta$L = 0 GT transitions. The GT states were studied up to 18.5 MeV. For the extraction of the B(GT) value, the proportionality between cross section and B(GT) was used. The standard B(GT) values were obtained from the 26 Si beta decay, where the mirror symmetry of B(GT) was obtained. The T = 2 GT states are expected in the region E x ≥ 13.5 MeV. By comparing with the results of 26 Mg(t, 3 He) 26 Na reactions, the isospin symmetry of T = 2 GT states is discussed. Due to the high-energy resolution, the decay widths $\Gamma$ for the states in the E x > 9 MeV region could be studied. The narrow width of the T = 2 states at 13.592 MeV is explained in terms of isospin selection rules.},
author = {Win, Kalayar and Fujita, Yoshitaka and Yeeoo, Yee and Fujita, Hiro},
booktitle = {EPJ Web of Conferences},
doi = {10.1051/epjconf/201920608003},
editor = {Yang, A. and Wang, W.Y. and Ng, S.C.C. and Chan, A.H. and Oh, C.H. and Phua, K.K.},
issn = {2100-014X},
month = {apr},
pages = {08003},
title = {{Analysis of high energy resolution data of $^{26}$Mg( $^3$He,t)$^{26}$Al reaction}},
url = {https://www.epj-conferences.org/10.1051/epjconf/201920608003},
volume = {206},
year = {2019}
}