\begin{document}$\theta=0^\circ$\end{document} and \begin{document}$45^\circ$\end{document}, and the incident deuteron energies are 250 and 300 keV, respectively. The neutron contributions from the 9Be(d,n)10B reaction are distributed relatively independently for the ground state and the first, second, and third excited states of 10B. The branching ratios of the 9Be(d,n)10B reaction for the different excited states of 10B are obtained for the neutron emission angles \begin{document}$\theta=0^\circ$\end{document} and \begin{document}$45^\circ$\end{document}, and the incident deuteron energies are 250 and 300 keV, respectively. The branching ratio of the 9Be(d,n)10B reaction for the third excited state decreases with increase in the incident deuteron energy, and the branching ratios for the ground state and the second excited state increase with increase in the neutron emission angle."> Measurements of neutron energy spectra of <sup>9</sup>Be(<i>d</i>,<i>n</i>)<sup>10</sup>B reaction with a thick beryllium target -
  • [1]

    Z. E. Yao, W. M. Yue, P. Luoet al., Atomic Energy Science and Technology42, 400 (2008)

  • [2]

    Z. E. Yao, H. X. Du, X. J. Tanet al., Chinese Journal of Computational Physics25, 744 (2008)

  • [3]

    H. Koivunoro, D. L. Bleuel, U. Nastasiet al., Applied Radiation and Isotopes61, 853 (2004)

  • [4]

    Y. B. Nie, J. Ren, X. C. Ruanet al., Annals of Nuclear Energy136, 107040 (2020)

  • [5]

    Z. Weiet al., J Radioanal Nucl Chem305, 455 (2015)

  • [6]

    W. J. Liet al., Nucl. Sci. Tech.30, 180 (2019)

  • [7]

    X. J. Sunet al., Chin. Phys. Lett.36, 112501 (2019)

  • [8]

    J. J. Maet al., Nucl. Sci. Ttch.29, 150 (2018)

  • [9]

    M. Yiǧit and E. Tel, Nucl. Sci. Tech.28, 165 (2017)

  • [10]

    Z. Wei, Y. Yanet al., Phys. Rev. C87, 054605 (2013)

  • [11]

    Z. Wei, J. R. Wanget al., Chin. Phys. C43, 054001 (2019)

  • [12]

    J. F. Zhang, X. C. Ruan, L. Houet al., High Power Laser and Particle Beams23, 209 (2011)

  • [13]

    R. Madeyet al., Phys. Rev. C14, 801 (1976)

  • [14]

    J. W. Meadows, Nucl. Instrum. Methods Phys. Res. A324, 239 (1993)

  • [15]

    Y. S. Park, A. Niileret al., Phys. Rev. C8, 1557 (1973)

  • [16]

    D. W. Glasgowet al., Nuclear Physics A99, 170 (1967)

  • [17]

    A. Belymam, A. Hoummada, J. Collotet al., Nucl. Instrum. Methods Phys. Res. B134, 217 (1998)

  • [18]

    F. M. Baumann, G. Domogala, H. Freieslebenet al., Nucl. Instrum. Methods Phys. Res. A247, 359 (1986)

  • [19]

    T. G. Milleret al., Phys. Rev. C1, 763 (1970)

  • [20]

    S. G. Buccinoet al., Physics Letters19, 234 (1965)

  • [21]

    T. N. Massey, D. K. Jacobs, S. I. Al-Quraishiet al., Journal of Nuclear Science and Technology39, 677 (2002)

  • [22]

    D. L. Smith, J. W. Meadows, and P. T. Guenther, Nucl. Instrum. Methods Phys. Res. A241, 507 (1985)

  • [23]

    S. Hashimoto, Y. Iwamoto, T. Satoet al., Progress in Nuclear Science and Technology4, 418 (2014)

  • [24]

    T. N. Massey, T. W. Covell, S. I. Al-Quraishiet al., Fusion Engineering and Design37, 57 (1997)

  • [25]

    S. Whittlestone, Journal of Physics D: Applied Physics10, 1715 (1977)

  • [26]

    Y. Iwamoto, Y. Sakamoto, N. Matsudaet al., Nucl. Instrum. Methods Phys. Res. A598, 687 (2009)

  • [27]

    H. J. Brede, G. Dietze, K. Kudoet al., Nucl. Instrum. Methods Phys. Res. A274, 332 (1989)

  • [28]

    T. Inada, K. Kawachi, and T. Hiramoto, Journal of Nuclear Science and Technology5, 22 (1968)

  • [29]

    X. Z. Wanget al., Nuclear Science and Techniques5, 193 (1994)

  • [30]

    K. A. Weaveret al., Phys. Med. Biol.18, 64 (1973)

  • [31]

    K. A. Weaver, J. D. Anderson, H. H. Barschallet al., Nuclear Sciense and Engineering52, 35 (1973)

  • [32]

    M. A. Lone, C. B. Bigham, J. S. Fraseret al., Nuclear Instruments and Methods143, 331 (1977)

  • [33]

    S. Nakayamaet al., Phys. Rev. C94, 014618 (2016)

  • [34]

    J. G. XU, H. Liet al., Nuclear Techniques31, 814 (2008)

  • [35]

    M. E. Capoulat, N. Sauzet, A. A. Valdaet al., Nucl. Instrum. Methods Phys. Res. B445, 57 (2019)

  • [36]

    M. Stefanik, P. Bem, M. Majerleet al., Radiation Physics and Chemistry140, 466 (2017)

  • [37]

    R. A. Coombeet al., Proc. Phys. Soc.80, 1218 (1962)

  • [38]

    Y. B. Zou, Y. Y. Pei, D. W. Mo et al, FNDA, 058(2006)

  • [39]

    G. Dietze and H. Klein, Report PTB-ND-22, (1982)

  • [40]

    D. Chen and W. B. Jia, Applied Neutron Physics, First edition (Beijing: Science Press, 2015), p.21 (in Chinese)

  • [41]

    G. R. Shen,Neutron Flight Time Method and Application,First edition (Beijing: Atomic Energy Press, 2007), p.108 (in Chinese)

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