Four-dimensional Langevin approach to low-energy nuclear fission of 
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Ishizuka, Chikako; Usang, M. D.; Ivanyuk, F. A.; Maruhn, J. A.; Nishio, K.; Chiba, Satoshi

doi:10.1103/physrevc.96.064616

Cited by 83 publications

(56 citation statements)

References 33 publications

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“…This behavior is apparently confirmed indirectly by experiments. In Langevin or Fokker-Planck [60][61][62][63][64][65], TDGCM [24,66], and scission-point [50][51][52][53] models the calculation of the FFs yields consider only a very limited range of nuclear shapes. In particular in such simulations one never introduces the octupole FF moments.…”

Section: The Presentmentioning

confidence: 99%

Nuclear Fission Dynamics: Past, Present, Needs, and Future

2020

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Recent developments in theoretical modeling and in computational power have allowed us to make significant progress on a goal not achieved yet in nuclear theory: a fully microscopic theory of nuclear fission. The complete microscopic description remains a computationally demanding task, but the information that can be provided by current calculations can be extremely useful to guide and constrain phenomenological approaches. First, a truly microscopic framework that can describe the real-time dynamics of the fissioning system can justify or rule out assumptions and approximations incompatible with an accurate quantum treatment or with our understanding of the inter nucleon interactions. Second, the microscopic approach can be used to obtain trends such as: the excitation energy sharing mechanism between fission fragments (FFs) with increasing excitation energy of the fissioning system, the angular momentum content of the FFs, or even to compute observables that cannot be otherwise calculated in phenomenological approaches or even measured, as in the case of astronomical environments. Merely the characterization of the trends would be of great importance for various application. We present here arguments that a truly microscopic approach to fission does not support the assumption of adiabaticity of the large amplitude collective motion in fission, particularly starting from the outer saddle down to the scission configuration. Such an assumption legitimize the introduction of a collective potential energy surface and inertia tensor, which are the essential elements of many simpler theoretical approaches. The nuclear shape evolution it is paradoxically 3...4 times slower than it would have been in the case of a pure adiabatic motion, and it is strongly overdamped. We demonstrate that the FFs properties are defined only after the FFs become separated significantly from each other. I. THE PASTIn a matter of days after Hahn and Strassmann [1] communicated their yet unpublished results to Lise Meitner, she and her nephew Otto Frisch [2] understood that an unexpected and qualitatively new type of nuclear reaction has been put in evidence and they dubbed it nuclear fission, in analogy to cell divisions in biology. Until that moment in time nuclear fission was considered a totally unthinkable process [3,4], "as excluded by the small penetrability of the Coulomb barrier [5], indicated by the Gamov's theory of alpha-decay" [2]. Meitner and Frisch [2] also gave the correct physical interpretation of the nuclear fission mechanism. They understood that Bohr's compound nucleus [6] is formed after the absorption of a neutron, which eventually slowly evolves in shape, while the volume remains constant, and that the competition between the surface energy of a nucleus and its Coulomb energy leads to the eventual scission. Meitner and Frisch [2] also correctly estimated the total energy released in this process to be about 200 MeV. A few months later Bohr and Wheeler [7] filled in all the technical details and the long road to develo...

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Section: The Presentmentioning

confidence: 99%

Nuclear Fission Dynamics: Past, Present, Needs, and Future

2020

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“…In the quantum optics the dimensionally of the Hilbert spaces of interest is small ≈ O(1). In nuclear fission for example, the number of degrees of freedom in Langevin studies is between 2 to 5 [2][3][4][5]24], which would correspond in the case of a quantum treatment to wave functions of 2 to 5 spatial variables and density matrices depending on 4 to 10 spatial variables alone. The solution of a Lindblad equation, even after a reduction to a Monte Carlo wave function approach, in the case of nuclear fission becomes easily prohibitive numerically.…”

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confidence: 99%

Unitary evolution with fluctuations and dissipation

2019

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“…The problem of the thermal decay of a metastable state (escape of a Brownian particle from a trap due to thermal fluctuations) is significant for different branches of natural sciences: in chemistry [1-3], biophysics [4,5], astrophysics [6], electronics [7,8], nuclear physics [9,10] etc. The decay rate is the principal characteristics of this process.…”

Section: Introductionmentioning

confidence: 99%

Accuracy of the analytical escape rate for a cusp barrier in the overdamping regime

Захаров

Chushnyakova

Gontchar

2020

J. Phys.: Conf. Ser.

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For the first time, the accuracy of the approximate analytical Kramers formula for the thermal decay rate over a cusp barrier, , is checked numerically for the overdamping regime. The numerical quasistationary rate, , which is believed to be exact within the statistical errors is evaluated by means of computer modeling of the stochastic Langevin-type dynamical equations. The agreement between and significantly depends upon the friction strength and the height of the barrier in comparison to the thermal energy. The difference between and decreases with the dimensionless damping parameter , however, does not become smaller than 10-20%. The unexpected growth of the difference between and with the governing parameter is observed.

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Four-dimensional Langevin approach to low-energy nuclear fission of U236

Cited by 83 publications

References 33 publications

Nuclear Fission Dynamics: Past, Present, Needs, and Future

Nuclear Fission Dynamics: Past, Present, Needs, and Future

Unitary evolution with fluctuations and dissipation

Accuracy of the analytical escape rate for a cusp barrier in the overdamping regime

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