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Using the IBA on Titan. Nuclear Model Codes at Yale Computer name: Titan. Connecting to SSH: Quick connect Host name: titan.physics.yale.edu User name: phy664 Port Number 22 Password: nuclear_codes cd phintm
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Nuclear Model Codes at YaleComputer name: Titan Connecting to SSH: Quick connect Host name: titan.physics.yale.edu User name: phy664 Port Number 22 Password: nuclear_codes cd phintm pico filename.in (ctrl x, yes, return) runphintm filename (w/o extension) pico filename.out (ctrl x, return)
Lets first do the three symmetries. Okey, dokey? Sph. Deformed
2.7 2.9 2.5 3.1 2.2 3.3 +2.0 +2.9 +1.4 +0.4 +0.1 -1 -0.1 -0.4 -2.0 -3.0 Now some calculations for real nuclei N = 10 R4/2
Lets do some together Pick a nucleus, any collective nucleus 152-Gd (N=10) 186-W (N=11) Data 0+ 0 keV 0 keV 2+ 344 122 4+ 755 396 6+ 1227 809 0+ 615 883 2+ 1109 737 R4/2 = 2.19 z~ 0.4 3.24 z ~ 0.7 R0/2 = -1.43 c ~ -1.32 +1.2 c ~ -0.7 For N = 10 and k = - 0.02 MeVe = 4 x 0.02 x 10 [ (1 – z)/ z] e = 0.8 x [0.6 /0.4] ~ 1.2 MeV e = 0.8 x [0.3/0.7] ~ 0.33 MeV At the end, need to normalize energies to first J = 2 state. For now just look at energy ratios. These parameters are starting points.
c Mapping the Entire Triangle with a minimum of data H =ε nd - Q Q Parameters: , c (within Q) /ε 2 parameters 2-D surface /ε varies from 0 to infinity /ε
0+ 4+ 2+ 2.5 1 2+ 0 0+ ζ H = c [ ( 1 – ζ ) nd - O(6) Qχ ·Qχ ] ζ = 1, χ = 0 4NB 0+ 2γ+ χ 3.33 4+ 2+ 0+ 2.0 4+ 1 2+ 2+ 1 ζ 0 0+ 0+ 0 U(5) SU(3) ζ = 0 ζ = 1, χ = -1.32 Spanning the Triangle