Structure of the Triplet of low-lying states in101Mo

Seyfarth, H.; Güven, H. H.; Kardon, B.; Lauppev, W. D.; Lhersonneau, G.; Sistemich, K.; Brant, S.; Kaffrell, Ν.; Maier-Komor, P.; Vonach, H.; Paar, V.; Vorkapić, D.; Meyer, R.A.

doi:10.1007/bf01284064

Cited by 10 publications

(5 citation statements)

References 31 publications

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“…This table gives for each of the 1207 primary nuclides the up to three most important contributing data and their influences (×100) on its mass, as given by the flow-of-information matrix. 99.8 7 Li−H 7 0.1 7 Li(n,γ) 8 Li 0.1 8 He− 7 Li 1.143 7 Li i 61.0 9 Be(p, 3 He) 7 Li i 39.0 6 Li(n,γ) 7 Li i 7 Be 100.0 7 Li(p,n) 7 Be 8 He 74.9 8 He− 7 33 Cl 20.1 33 Cl i (IT) 33 Cl Cl i 63.1 33 Cl i (IT) 33 Cl 36.9 32 S(p,γ) 33 109 In− 110 Cd() 111 In 11.7 113 In(p,t) 111 In− 115 In() 113 187 Tl m 13.9 187 Tl m (IT) 187 Tl 13.9 187 Tl m (α) 183 199 Bi m (α) 195 Tl 21.9 195 Tl−u 21.7 195 Tl− 133 Cs 1.466 Pb 59.1 195 Pb−u 40.9 195 Pb m (IT) 195 Pb Pb m 59.0 195 Pb m (IT) 195 Pb 41.0 199 Po m (α) 195 Pb m Bi 89.5 195 Bi− 133 199 Bi 33.6 199 Bi m (IT) 199 Bi 27.7 199 Bi−u Bi m 63.9 199 Bi m (IT) 199 Bi 36.1 199 Bi m (α) 195 229 Th 25.5 230 Th(d,t)…”

Section: Explanation Of Tablementioning

confidence: 99%

The AME2016 atomic mass evaluation (II). Tables, graphs and references

Wang¹,

et al. 2017

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This paper is the second part of the new evaluation of atomic masses, AME2016. Using least-squares adjustments to all evaluated and accepted experimental data, described in Part I, we derive tables with numerical values and graphs to replace those given in AME2012. The first table lists the recommended atomic mass values and their uncertainties. It is followed by a table of the influences of data on primary nuclides, a table of various reaction and decay energies, and finally, a series of graphs of separation and decay energies. The last section of this paper lists all references of the input data used in the AME2016 and the NUBASE2016 evaluations (first paper in this issue).AMDC: http://amdc.impcas.ac.cn/ Contents The AME2016 atomic mass evaluation (II). Tables, graphs and referencesAcrobat PDF (293 KB) Table I. The 2016 Atomic mass tableAcrobat PDF (273 KB) Table II. Influences on primary nuclidesAcrobat PDF (160 KB) Table III. Nuclear-reaction and separation energiesAcrobat PDF (517 KB) Graphs of separation and decay energiesAcrobat PDF (589 KB) References used in the AME2016 and the NUBASE2016 evaluationsAcrobat PDF (722 KB)

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Section: Explanation Of Tablementioning

confidence: 99%

The AME2016 atomic mass evaluation (II). Tables, graphs and references

Wang¹,

et al. 2017

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“…These findings for 1~ are in accordance with the general observation that ground-state deformation sets in at N = 60 in this nuclear region and that /~q reaches values of 0.34). 4. It should be noted that the isotope 1~…”

Section: Introductionmentioning

confidence: 97%

The structure of the deformed nucleus 42 103 Mo61

Liang

Ohm

Ragnarsson³

et al. 1993

Z. Physik A - Hadrons and Nuclei

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Abstract. The lifetimes of the three lowest excited members of the rotational ground-state band of 1~ at 102.6, 241.1 and 433.2 keV as well as of the levels at 353.8 and 456.1 keV have been determined through a measurement of the delayed coincidences between/~ particles from the decay of the parent l~ and the 7 rays which depopulate the levels. A plastic and a BaF 2 detector have been used for the /~ and 7 rays, respectively, in these experiments at the fission product separator JOSEF. The results for all three band members evince that this nucleus has a sizeable deformation, with a value of/3q=0.34(1). This value is larger than that of the neighbouring eveneven Mo isotopes which indicates an odd-even effect. On the other hand it confirms the observation that the Mo nuclei are in general less strongly deformed than their Sr and Zr isotones. Particle-rotor model calculations with the Nilsson parameters ~c = 0.084, j~ = 0.28 provide a good description of the ground-state band and of a side band based on the 346.5 keV level, including the new lifetimes. This substantiates the Nilsson orbital assignments of [41113/2 + and [532]5/2-for these two bands, respectively, where the sideband is strongly affected by a [54113/2-admixture. There is evidence for an additional band based on the 641.1 keV level for which the assignment [42213/2 + is proposed.

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“…Molybdenum isotopes have been studied in neutron transfer experiments. There are several published studies of the (d, p) and (p, d) reactions on 100 Mo [22][23][24][25][26][27][28][29][30][31]. Studies of both these reactions, albeit fewer in number, have been made on targets of 98 Mo [27,[32][33][34] and 102 Ru [35][36][37][38][39].…”

Section: Introductionmentioning

confidence: 99%