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Oscillations in mass asymmetry in second and third minima in actinides 1. Second & third minima in actinides 2. Barrier calculations: Micro-macro vs. selfconsistent.

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Presentation on theme: "Oscillations in mass asymmetry in second and third minima in actinides 1. Second & third minima in actinides 2. Barrier calculations: Micro-macro vs. selfconsistent."— Presentation transcript:

1 Oscillations in mass asymmetry in second and third minima in actinides 1. Second & third minima in actinides 2. Barrier calculations: Micro-macro vs. selfconsistent calculations 3. Oscillations in mass asymmetry in the first & second minima 4. Vibrations in the III minima; different meaning of the K=0 mode 5. Conclusions M. Kowal & J. Skalski

2 Polikanov et al. (1962) Discovery of isomeric fission Strutinsky (1967) Calculated second minima Specht et al. (1972) Identification of the rotational band with large moment of inertia in 240Pu

3 At present: fission isomers in 34 nuclei, from U to Bk, in that 11 in Pu, 10 in Am half-lives: 6 ps to 14 ms (in 242Am) In some nuclei, there are double isomers (supposed spin isomeric states in II min.) Measured quadrupole moments: 236U 32(5) b 238U 29(3) b 236Pu 37(11) b 239Pu 36(4) b from optical isotope shift & hyperfine structure: 240Am 33.9 b 242Am 33.5(1) b 244Am 34.4 b

4 Third minima: Th,U First predicted: P. Moller, S.G. Nilsson and R.K. Sheline (1972) then Howard & Moller (1980) – rather shallow III-rd minima S.Cwiok et al. – rather deep III-rd minima some, not all, HF calculations give III-rd minima, BUT they often differ from macro-micro results Experiments: 1)Studies of microstructure in the resonances of fission probability found using (n,f), (t,pf) and (d,pf) reactions B.B. Back et al. (1972) J. Blons et al. (1975) recent claims of III-rd minima in 232,234,236U 2) Also observations of asymmetric angular distribution of light fission fragments around 232Th

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6 Results (rather preliminary)

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8 Difficulties with energy minimization with YPE

9 III min : 120 or 170 b

10 III min 140 or 195 b

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13 ZNE ( I ) MINB ( I )E (II) MINB (II) E(III) a b3=0,6 E(III) b B3=0,3B(III) 90140-2,36,22.5-----4.84.5---- 90142-2,56,92.06,44.84.49,4 92140-2,74,53.05,72.74.26,7 92142-2,95,12.56,62.44.07,7 92144-3,05,92.06,22.23.87,3 94146-3,96,92.46,00.33.35,8

14 Vibrations in mass asymmetry: -Axially deformed, mass-symmetric I-st and II-nd minima Well defined K, but the phonon angular momentum is not well defined in the intrinsic frame. -We mix vibrations related to spherical harmonics 3,5 & 7 and fixed K=0,1,2,3. - Method: small vibrations det (C – omega^2 B) = 0, where C&B are 3 by 3 stiffness&mass matrices -Quadratic form C well approximates energy around the minima - For B we take cranking masses at the minimum (not very bright).

15 Parabolic fit to E(beta30) in the II-nd well

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23 III-rd minima show large mass-asymmetry. One expects nearly degenerate, alternating parity gs band. The K=0 vibration means a different thing than in the I and II well: it is no a piori reason that it be small. Since the III-rd minima are axially symmetric, the scheme of calculating vibration energies is kept.

24 III MIN (b3=0,6) ZNAALL SQRT (C3i/B3i) OSCILLATION 0- 901402301626,12154, 901422321330,12337,8 921402321888,83055,4 921422341991,63181,2 921442362164,73297,3 941462401959,83350,0 OSCILLATION 1- 901402301741,02980,3 901422321821,72988,7 921402321659,62538,9 921422341800,32751,8 921442362004,72851,9 941462401889,23044,8 OSCILLATION 2- 901402301930,52145,1 901422322138,82415,9 921402322372,42736,2 921422342100,22578,9 921442362529,52886,6 941462401816,32285,4 III MIN (b3=0,3) ZNAALL SQRT (C3i/B3i) OSCILLLATION 0- 901402301351,32060,9 901422321436,32161,5 921402321129,32065,6 921422341226,42239,3 921442361322,32252,5 941462401361,62122,8 OSCILLATION 1- 901402301366,92271,9 901422321492,92391,4 921402321464,62208,7 921422341500,62270,4 921442361419,22287,8 941462401265,52133,5 OSCILLATION 2- 901402301720,02080,3 901422321648,72128,8 921402321768,92019,2 921422341680,32023,4 921442361634,52018,3 941462401851,32173,8

25 Conclusions: 1.Within WS+YpE macro-micro approach one obtains rather deep & double mass-asymmetric III-rd minima. 2. Within WS+LSD they become single, but remain deep. 3. They often do not show in the HF calc., and are shallower in P. Moller’s results. ! So what is the truth? Is experiment clear enough? 4. Mass-asymmetry („octupole”) vibrations: - not a bad agreement in the I-st min (even the order of K is reproduced) - too high energies in the second min. in 240Pu – especially if K=0 is as low as suggested by expt. - no very low lying vibrational states in the III-rd well.

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