ADOPTED LEVELS for 227Po
Author: Ictp-2014 Workshop Group | Citation: Nucl. Data Sheets 132, 257 (2016) | Cutoff date: 15-Jan-2016
Author: B. Singh | Citation: ENSDF | Cutoff date: 15-JAN-2016
Full ENSDF file | Adopted Levels (PDF version)
Q(β-)=4800 keV SY | S(n)= 3340 keV SY | S(p)= 10200 keV CA | Q(α)= 1470 keV CA | ||
Reference: 2012WA38,1997MO25 |
E(level) (keV) | T1/2(level) |
0 | > 300 ns % β- = ? |
Additional Level Data and Comments:
E(level) | Jπ(level) | T1/2(level) | Comments |
0 | > 300 ns % β- = ? | Production cross section measured in 2010Al24, values are given in figure 2, plot of σ versus mass number for Po isotopes. Statistical uncertainty=10%, systematic uncertainty=20%. |
227Po evaluated by B. Singh.
2010Al24: 227Po nuclide identified in 9Be(238U,X) reaction with a beam energy of 1 GeV/nucleon produced by the SIS synchrotron at GSI facility. Target=2500 mg/cm2. The fragment residues were analyzed with the high resolving power magnetic spectrometer Fragment separator (FRS). The identification of nuclei was made on the basis of magnetic rigidity, velocity, time-of-flight, energy loss and atomic number of the fragments using two plastic scintillators and two multisampling ionization chambers. The FRS magnet was tuned to center on 210Au, 216Pb, 219Pb, 227At and 229At nuclei along the central trajectory of FRS.
Unambiguous identification of nuclides required the separation of different charge states of the nuclei passing through the FRS. At 1 GeV/nucleon incident energy of 238U, fraction of fully stripped 226Po nuclei was about 89%. Through the measurement of difference in magnetic rigidity in the two sections of the FRS and the difference in energy loss in the two ionization chambers, the charge state of the transmitted nuclei was determined, especially, that of the singly charged (hydrogen-like) nuclei which preserved their charge in the current experimental setup. Measured production cross sections with 10% statistical and 20% systematic uncertainties
Criterion established in 2010Al24 for acceptance of identification of a new nuclide: 1. number of events should be compatible with the corresponding mass and atomic number located in the expected range of positions at both image planes of the FRS spectrometer; 2. number of events should be compatible with >95% probability that at least one of the counts does not correspond to a charge-state contaminant. Comparisons of measured σ with model predictions using the computer codes COFRA and EPAX.
Q-value: Estimated uncertainties in 2012Wa38: 500 for Q(β-), 570 for S(n)
Q-value: Q(β-), and S(n) from 2012Wa38; S(p) and Q(α) from 1997Mo25
Q-value: S(2n)=8390 500, Q(β-n)=-410 500 (syst,2012Wa38), S(2p)=19320 (1997Mo25,theory)