Différences entre les versions de « RPA abstracts »
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''2 - Institute for Nuclear Science and Techniques, Vietnam Atomic Energy Commission'' | ''2 - Institute for Nuclear Science and Techniques, Vietnam Atomic Energy Commission'' | ||
''Hanoi - Vietnam'' | ''Hanoi - Vietnam'' | ||
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The Selfconsistent Quasiparticle RPA (SCQRPA) is constructed [1] to study the effects of fluctuations on pairing properties in finite systems. | The Selfconsistent Quasiparticle RPA (SCQRPA) is constructed [1] to study the effects of fluctuations on pairing properties in finite systems. | ||
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Several issues such as the smoothing of superfluid-normal phase transition, thermally assisted pairing in hot rotating nuclei, extraction of the nuclear pairing gap using an | Several issues such as the smoothing of superfluid-normal phase transition, thermally assisted pairing in hot rotating nuclei, extraction of the nuclear pairing gap using an | ||
improved odd-even mass difference are discussed [4]. Finally, a novel approach of embedding the projected SCQRPA eigenvalues in the canonical ensemble (CE) is proposed (the CE-SCQRPA) [5]. Applied to a doubly-folded equidistant multilevel pairing model, the proposed CE-SCQRPA produces results in good agreement with those obtained by using the exact eigenvalues, whenever the latter are possible, and is workable also for large values of particle number (N>14), where the diagonalisation of the pairing Hamiltonian is impracticable. | improved odd-even mass difference are discussed [4]. Finally, a novel approach of embedding the projected SCQRPA eigenvalues in the canonical ensemble (CE) is proposed (the CE-SCQRPA) [5]. Applied to a doubly-folded equidistant multilevel pairing model, the proposed CE-SCQRPA produces results in good agreement with those obtained by using the exact eigenvalues, whenever the latter are possible, and is workable also for large values of particle number (N>14), where the diagonalisation of the pairing Hamiltonian is impracticable. | ||
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''References'' | ''References'' | ||
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[5] N. Quang Hung and N. Dinh Dang, in preparation | [5] N. Quang Hung and N. Dinh Dang, in preparation | ||
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== '''Title of the talk''' == | == '''Title of the talk''' == | ||
Version du 3 décembre 2009 à 10:26
Please add below your talk abstract.
The Selfconsistent Quasiparticle RPA and Its Description of Thermal Pairing Properties in Nuclei
Nguyen Dinh Dang
1 - Heavy-Ion Nuclear Physics Laboratory, Nishina Center for Accelerator-Based Science RIKEN 2-1 Hirosawa, Wako city, 351-0198 Saitama, Japan
2 - Institute for Nuclear Science and Techniques, Vietnam Atomic Energy Commission Hanoi - Vietnam
The Selfconsistent Quasiparticle RPA (SCQRPA) is constructed [1] to study the effects of fluctuations on pairing properties in finite systems. The theory is applied to nuclei at finite temperature [2] and angular momentum [3]. Particle number projection is taken into account within the Lipkin-Nogami method. Several issues such as the smoothing of superfluid-normal phase transition, thermally assisted pairing in hot rotating nuclei, extraction of the nuclear pairing gap using an improved odd-even mass difference are discussed [4]. Finally, a novel approach of embedding the projected SCQRPA eigenvalues in the canonical ensemble (CE) is proposed (the CE-SCQRPA) [5]. Applied to a doubly-folded equidistant multilevel pairing model, the proposed CE-SCQRPA produces results in good agreement with those obtained by using the exact eigenvalues, whenever the latter are possible, and is workable also for large values of particle number (N>14), where the diagonalisation of the pairing Hamiltonian is impracticable.
References
[1] N. Quang Hung and N. Dinh Dang, Phys. Rev. C 76 (2007) 054302 and 77 (2008) 029905(E).
[2] N. Dinh Dang and N. Quang Hung, Phys. Rev. C 77 (2008) 064315.
[3] N. Quang Hung and N. Dinh Dang, Phys. Rev. C 78 (2008) 064315.
[4] N. Quang Hung and N. Dinh Dang, Phys. Rev. C 79 (2009) 054328.
[5] N. Quang Hung and N. Dinh Dang, in preparation
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