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Alpha decay half-lives of even-even superheavy elements
报告人:王永佳 指导老师:张鸿飞 兰州大学核科学与技术学院 第13届核结构讨论会 内蒙古赤峰学院
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Outline Summary Introduction Generalized Liquid Drop Model (GLDM)
Numerical results and discussions Summary
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Introduction In 1911, Geiger -Nuttall law: Difference:
In 1928, G. Gamow created the QM theory of alpha decay. 1928 In 1928, W. Gurney and U. Condon obtained a general idea of the mysterious instability of the nucleus. Difference: Gurney and Condon argued that the same QM tunneling analysis should also be applicable to beta decay, whereas Gamow already knew that beta decay posed a much deeper theoretical challenge.
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Various models Theoretical models: Semi-empirical formula:
Viola–Seaborg–Sobiczewski: G. Royer and H.F. Zhang : Theoretical models: Cluster model, DDCM , GDDCM GLDM, DDM3Y, unified fission model [Ref.] J. Phys. G: Nucl. Part. Phys. 35 (2008)
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Introduction Superheavy elements Decay modes: alpha decay
and spontaneous fission Identification Dubna: 48Ca+249Bk ,294117 GSI : 48Ca+244Pu ,289114 [Ref.] Phys. Rev. Lett. 104(2010) [Ref.] Phys. Rev. Lett. 104(2010)
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Our method Generalized liquid drop model (GLDM) Preformation factor
Assault frequency [For heavy even-even nuclei Z>82 and N>126] The standard deviation between the extracted data and the values obtained from this Eq. is only , implying that the average deviation between the theoretical estimates and the experimental data for alpha decay half-lives of heavy even-even nuclei will be = 1.45. [Ref.] wang yong-jia and zhang hong-fei at el. CHIN. Phys. Lett. 27(6)
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Alpha decay energy [Ref.] T. Dong and Z. Ren, Phys. Rev. C 77, (2008). [Ref.] B. Buck, A. C. Merchant and S. M. Perez, Phys. Rev. C45(1992), 2247. [Ref.] E.L. Medeiros et al. , J. Phys. G 32(2006) B23.
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Alpha decay energy The previously mentioned formula can be simplified:
Royer formula: [Ref.] G. Royer and H. F. Zhang Phys. Rev. C [Ref.] Jianmin Dong at el. Phys. Rev. C81(2010)064309
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Compared with experimental data
AZ Qexp(MeV) QDong(MeV) T(exp.) T(cal.) 294118 11.81±0.06 11.718 0.89(+1.07/-0.31)ms 0.94ms 292116 10.80±0.07 10.810 18(+16/-6)ms 48.4ms 290116 11.00±0.0.08 11.087 7.1(+3.2/-1.7)ms 16.1ms 288114 10.09±0.07 10.164 0.69 (+0.17/-0.11)s 0.827s 286114 10.33±0.06 10.447 0.26s 0.18s 284112 SF 9.510 99(+24/-16)ms 29.34s 282112 9.799 0.82(+0.30/-0.18)ms 1.56s 270110 11.24±0.05 11.092 100(+140/-40)s 0.93s 266108 10.38±0.02 10.481 2.3(+1.3/-0.6)ms 2.32ms
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Compared with experimental data
AZ Qexp(MeV) QDong(MeV) T(exp.) T(cal.) 264108 10.848 10.766 81s 20.5s 260106 9.92±0.03 10.155 9.5(+2/-2)ms 8.1ms 260104 8.947 8.935 1s 0.846s 258104 9.296 9.238 92ms 82.5ms 256104 8.966 9.109 0.304s 0.596s Experimental Data come from: Yu. Ts. Oganessian et al., Phys. Rev. C 69, (R) (2004);70, (2004); 72, (2005); 74, (2006); 76, (R) (2007) and G. Audi et al. Nucl. Phys. A 729 (2003) 3.
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Superheavy elements Cold fusion:Z<113 Hot fusion:48Ca, 56Fe :
Dubna: Ca+Pu,Am,Cm,Bk,Cf GSI: Ca+Pu Ds---277Hs+alpha Future: Ca + Md Fe + Md Nuclei which Z<127 would be synthesized in the near future.
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Alpha decay and spontaneous fission
Phys. Rev. C78(2008) For 45 nuclei Region from 232Th to
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Very long SF half-life, why?
Z. Ren, et al. NPA 759 (2005) 64. Chang Xu, et al. PRC78 (2008) K.P. Santhosh et al. NPA832(2010)220
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Summary We improved the assault frequency in the GLDM.
The improved model agrees with the experimental data of heavy nuclei within a factor of 2. General predictions
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Thanks for your attention!
Thanks for the organizer of this conference!
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