Universal damping mechanism of quantum vibrations in deep sub-barrier fusion reactions

We demonstrate the damping of quantum octupole vibrations near the touching point when two colliding nuclei approach each other in the mass-asymmetric $^{208}$Pb + $^{16}$O system, for which the strong fusion hindrance was clearly observed. We, for the first time, apply the random-phase approximation method to the heavy-mass asymmetric di-nuclear system to calculate the transition strength $B$(E3) as a function of the center-of-mass distance. The obtained $B$(E3) strengths are substantially damped near the touching point, because the single-particle wave functions of the two nuclei strongly mix with each other and a neck is formed. The energy-weighted sums of $B$(E3) are also strongly correlated with the damping factor which is phenomenologically introduced in the standard coupled-channel calculations to reproduce the fusion hindrance. This strongly indicates that the damping of the quantum vibrations universally occurs in the deep sub-barrier fusion reactions.

[1]  A. S. Umar,et al.  How the Pauli exclusion principle affects fusion of atomic nuclei , 2016, 1610.02663.

[2]  Yvonne Koch,et al.  A Primer In Density Functional Theory , 2016 .

[3]  T. Ichikawa Systematic investigations of deep sub-barrier fusion reactions using an adiabatic approach , 2015, 1510.00806.

[4]  B. Back,et al.  Recent developments in heavy-ion fusion reactions , 2014 .

[5]  R. Broglia,et al.  Fifty years of nuclear BCS : pairing in finite systems , 2013 .

[6]  K. Matsuyanagi,et al.  Damping of Quantum Vibrations Revealed in Deep Sub-barrier Fusion , 2013, 1302.7115.

[7]  K. Hagino,et al.  Subbarrier Fusion Reactions and Many-Particle Quantum Tunneling , 2012, 1209.6435.

[8]  D. Rowe,et al.  Nuclear Collective Motion: Models and Theory , 2010 .

[9]  J. Wood,et al.  Fundamentals Of Nuclear Models: Foundational Models , 2010 .

[10]  K. Hagino,et al.  Signature of smooth transition from sudden to adiabatic states in heavy-ion fusion reactions at deep sub-barrier energies. , 2009, Physical review letters.

[11]  G. Milburn,et al.  Beyond the coherent coupled channels description of nuclear fusion. , 2007, Physical review letters.

[12]  H. Esbensen,et al.  Hindrance of {sup 16}O + {208}Pb fusion at extreme sub-barrier energies. , 2007, 0711.3189.

[13]  K. Hagino,et al.  Existence of a one-body barrier revealed in deep subbarrier fusion , 2007, 0704.2825.

[14]  H. Esbensen,et al.  Hindrance of heavy-ion fusion due to nuclear incompressibility. , 2006, Physical review letters.

[15]  P. Ring,et al.  Extended density functionals in nuclear structure physics , 2004 .

[16]  K. Hagino,et al.  A program for coupled-channel calculations with all order couplings for heavy-ion fusion reactions , 1999, nucl-th/9903074.

[17]  W. Myers,et al.  Nuclear ground state masses and deformations , 1993, nucl-th/9308022.

[18]  I. Ragnarsson,et al.  Shapes and shells in nuclear structure , 1995 .

[19]  Esbensen,et al.  Higher-order coupling effects in low energy heavy-ion fusion reactions. , 1987, Physical review. C, Nuclear physics.

[20]  G. Royer,et al.  Static and dynamic fusion barriers in heavy-ion reactions , 1985 .

[21]  W. Gelletly Elementary Modes of Excitation in Nuclei: Proceedings of the International School of Physics ‘Enrico Fermi’ Course LXIX , 1979 .

[22]  G. Bertsch,et al.  Nuclear response in the continuum , 1975 .

[23]  J. L. Norton,et al.  New Calculation of Fission Barriers for Heavy and Superheavy Nuclei , 1972 .

[24]  E. O. Wiig Elementary Theory of Nuclear Shell Structure. , 1956 .