FRESCO - FRES 3.4: Coupled Reaction Channels Assuming NAMELIST input. 16O+208Pb 80 MeV, 17O + 15N + 12C channels, S(212Po) = 1.30 BARE in TR. 0.025 30.000 0.500 0.025 6.000 0.000 0.000 0.000 0.000 0.000 Centre-of-mass Range is 1202 * 0.0250 fm., Maximum at 30.00 fm., Interpolating NL forms every 0.50 fm. Non - locality width is 241 * 0.0250 fm., Maximum of 6.00 fm., Centred at 0.00 fm. 2-Nucleon Separation of 0 * 0.5000 fm., Maximum of 0.00 fm., Minimum at 0.00 fm. Maximum single particle bins of 30.0000 fm. M,Mint = 1201 1201 Range of total J is 0.0 <= J <= 100.0 (at least 0.0) and Absorbtion => 0.1000 mb. Dry Run = F, CC set limits = 0 0, Relativistic kinematics = , Both/Far/Near Analyses = 1 Cross Sections (and up to T0 for 0=projectile) for Theta from 80.0 to 180.0 in steps of 2.5 degrees, DGAM=0, Coordinates = 0 (Mads) Lower Radial Cutoff = maximum of 4.00*L*h & Turn-10.0 fm., Lower Cutoff for Couplings = 0.0 fm. Iterate Couplings between 0 and 30 times, to 0.010 % if sooner. Convergence failures are fatal Block solved exactly = 3 chs., with Pade = 1 & Isocen = =0, NOSOL = F, initwf = 0 NL quadrature with 24 Gaussian points, Calculate multipoles up to 106 from 0 M-transfers for lp+lt greater than or equal to 6, Angular Integration Cutoff below 1.5625 % Range of successive Continuum BINS = 1.2000 , formed by integration with DK < 0.0000 / fm. Trace switches are : CHANS = 1, LISTCC = 0, TRENEG = 0, CDETR = 0, SMATS = 2, XSTABL = 0, NLPL = 0 WAVES = 0, LAMPL = 0, VEFF = 1, KFUS = 20, WDISK = 0, BPM = 0, MELFIL = 0 CDCC = 0, NFUS = 0 CAUTION: WAVE FUNCTIONS ARE NOT IMPROVED BY PADE ACCELERATION - ONLY THE S-MATRIX ELEMENTS. WAVE FUNCTIONS SIMPLY RESCALED BY S-MATRIX CORRECTIONS Using unit mass = 1.000000 amu and 1/fine-structure constant = 137.03599 ( 1.000000 * true ) with hc = 197.32705 MeV.fm, thus 2*amu/hbar^2 = 0.0478450 = 1/20.9008 and Coulomb constant = 0.1574855 so e^2 = 1.43997, and nuclear magneton= 0.1261183 Now pre-scan input and save to file 3 *********** PARTITION NUMBER 1 ****************************************************************************************** PROJ=16-O MASS= 15.9949 Z= 8.0, # STATES= 5T, TARG=PB-208 MASS=207.9770 Z= 82.0, Q-VALUE = 0.0000 MEV. 1: J= 0.0+ (B# 1), E= 0.0000, K= 0.0 Potl# 1 J= 0.0+ (B# 1), E= 0.0000, K= 0.0 2: J= 3.0- (B#-1), E= 6.1300, K= 0.0 Potl# 1 J= 0.0+ (B# 1), E= 0.0000, K= 0.0 (Just State 1) 3: J= 0.0+ (B# 1), E= 0.0000, K= 0.0 Potl# 1 J= 3.0- (B#-1), E= 2.6100, K= 0.0 (Just State 1) 4: J= 0.0+ (B# 1), E= 0.0000, K= 0.0 Potl# 1 J= 2.0+ (B# 1), E= 4.0700, K= 0.0 (Just State 1) 5: J= 0.0+ (B# 1), E= 0.0000, K= 0.0 Potl# 1 J= 5.0- (B#-1), E= 3.2000, K= 0.0 (Just State 1) *********** PARTITION NUMBER 2 ****************************************************************************************** PROJ=17-O MASS= 16.9990 Z= 8.0, # STATES= 6T, TARG=PB-207 MASS=206.9760 Z= 82.0, Q-VALUE = -3.2330 MEV. 1: J= 2.5+ (B# 1), E= 0.0000, K= 0.5 Potl# 2 J= 0.5- (B#-1), E= 0.0000, K= 0.5 2: J= 2.5+ (B# 1), E= 0.0000, K= 0.5 Potl# 2 J= 2.5- (B#-1), E= 0.5710, K= 0.5 (Just State 1) 3: J= 2.5+ (B# 1), E= 0.0000, K= 0.5 Potl# 2 J= 1.5- (B#-1), E= 0.8980, K= 0.5 (Just State 1) 4: J= 0.5+ (B# 1), E= 0.8710, K= 0.5 Potl# 2 J= 0.5- (B#-1), E= 0.0000, K= 0.5 (Just State 1) 5: J= 0.5+ (B# 1), E= 0.8710, K= 0.5 Potl# 2 J= 2.5- (B#-1), E= 0.5710, K= 0.5 (Just State 4) (Just State 2) 6: J= 0.5+ (B# 1), E= 0.8710, K= 0.5 Potl# 2 J= 1.5- (B#-1), E= 0.8980, K= 0.5 (Just State 4) (Just State 3) *********** PARTITION NUMBER 3 ****************************************************************************************** PROJ=15-N MASS= 14.9998 Z= 7.0, # STATES= 2T, TARG=BI-209 MASS=208.9800 Z= 83.0, Q-VALUE = -8.3239 MEV. 1: J= 0.5- (B#-1), E= 0.0000, K= 0.5 Potl# 3 J= 3.5- (B#-1), E= 0.8966, K= 0.5 2: J= 0.5- (B#-1), E= 0.0000, K= 0.5 Potl# 3 J= 1.5- (B#-1), E= 3.1180, K= 0.5 (Just State 1) 0****** WARNING : COMPARED WITH PARTITION 1, THIS PARTITION HAS TOTAL MASS & CHARGE EXCESSES -0.00105 & 0.0000 *********** PARTITION NUMBER 4 ****************************************************************************************** PROJ=12-C MASS= 12.0000 Z= 6.0, # STATES= 1T, TARG=PO-212 MASS=212.0000 Z= 84.0, Q-VALUE = -20.0000 MEV. 1: J= 0.0+ (B# 1), E= 0.0000, K= 0.0 Potl# 8 J= 0.0+ (B# 1), E= 0.0000, K= 0.0 0****** WARNING : COMPARED WITH PARTITION 1, THIS PARTITION HAS TOTAL MASS & CHARGE EXCESSES 0.00662 & 0.0000 ************************************************************************************************************************************ The following POTENTIALS are defined : KP# TYPE IT SHAPE at V1 r1 a1 V2 r2 a2 A-in A-used A#1 A#2 r0c ac h @ 1 1 0=Coulomb 0=CHARGE (WS) 1 208.000 16.000 1.2000 0.0000 0.0000 0.0000 0.000 602.245 0.02500 Mn(E1) Mn(E2) Mn(E3) ..... 1 10=Proj. defrm 10=derivatives 2 0.0000 0.0000 37.6000 0.0000 0.0000 0.0000 0.000 10.134= RADIUS At 2 is k = 3 (Potl. beta = 0.01892) Beta of proj. = 0.71207 (using radius of 3.024 fm.). Mn(E1) Mn(E2) Mn(E3) ..... 1 13=Targ. table 10=derivatives 3 0.0000 54.4500 815.0000 0.000023800.0000 0.0000 0.000 10.134= RADIUS Coulomb reduced matrix element 1 <- 3 of k = 3 (at 4 from 1 p) == 815.0000 Coulomb reduced matrix element 3 <- 1 of k = 3 (at 4 from 1 p) == 815.0000 Coulomb reduced matrix element 1 <- 4 of k = 2 (at 3 from 1 p) == 54.4500 Coulomb reduced matrix element 4 <- 1 of k = 2 (at 3 from 1 p) == 54.4500 Coulomb reduced matrix element 1 <- 5 of k = 5 (at 5 from 1 p) ==23800.0000 Coulomb reduced matrix element 5 <- 1 of k = 5 (at 5 from 1 p) ==23800.0000 Step 4 <- 1 of k = 2 (Potl. beta = 0.02708) 1 @ 3 Beta of targ. = 0.05502 (using radius of 7.110 fm.). Step 3 <- 3 of k = 2 (Potl. beta =-0.00000) 1 @ 3 Step 5 <- 3 of k = 2 (Potl. beta = 0.00000) 1 @ 3 Step 1 <- 4 of k = 2 (Potl. beta = 0.02708) 1 @ 3 Beta of targ. = 0.05502 (using radius of 7.110 fm.). Step 4 <- 4 of k = 2 (Potl. beta =-0.00000) 1 @ 3 Step 3 <- 5 of k = 2 (Potl. beta = 0.00000) 1 @ 3 Step 5 <- 5 of k = 2 (Potl. beta =-0.00000) 1 @ 3 Step 3 <- 1 of k = 3 (Potl. beta = 0.04001) 1 @ 4 Beta of targ. = 0.11583 (using radius of 7.110 fm.). Step 1 <- 3 of k = 3 (Potl. beta = 0.04001) 1 @ 4 Beta of targ. = 0.11583 (using radius of 7.110 fm.). Step 4 <- 3 of k = 3 (Potl. beta =-0.00000) 1 @ 4 Step 3 <- 4 of k = 3 (Potl. beta =-0.00000) 1 @ 4 Step 5 <- 4 of k = 3 (Potl. beta = 0.00000) 1 @ 4 Step 4 <- 5 of k = 3 (Potl. beta = 0.00000) 1 @ 4 Step 5 <- 1 of k = 5 (Potl. beta = 0.01138) 1 @ 5 Beta of targ. = 0.06691 (using radius of 7.110 fm.). Step 4 <- 3 of k = 5 (Potl. beta = 0.00000) 1 @ 5 Step 3 <- 4 of k = 5 (Potl. beta = 0.00000) 1 @ 5 Step 5 <- 4 of k = 5 (Potl. beta =-0.00000) 1 @ 5 Step 1 <- 5 of k = 5 (Potl. beta = 0.01138) 1 @ 5 Beta of targ. = 0.06691 (using radius of 7.110 fm.). Step 4 <- 5 of k = 5 (Potl. beta =-0.00000) 1 @ 5 1 1=Volume 1=WS squared 6 0.0000 1.1790 0.6580 10.0000 1.0000 0.4000 0.000 602.245 1 1=Volume 0=Woods-Saxon 6 60.5000 1.1790 0.6580 0.0000 0.0000 0.0000 0.000 602.245 Def1 Def2 Def3 ..... 1 10=Proj. defrm 11=quadrat,k>0 7 0.0000 0.0000 2.1500 0.0000 0.0000 0.0000 0.000 9.956= RADIUS At 7 is k = 3 (Potl. beta = 0.21594) Beta of proj. = 0.72369 (using radius of 2.971 fm.). Def1 Def2 Def3 ..... 1 13=Targ. table 11=quadrat,k>0 8 0.0000 0.4000 0.8000 0.0000 0.4680 0.0000 0.000 9.956= RADIUS Nuclear reduced matrix element 1 <- 3 of k = 3 (at 9 from 6 p) == 0.8000 Nuclear reduced matrix element 3 <- 1 of k = 3 (at 9 from 6 p) == 0.8000 Nuclear reduced matrix element 1 <- 4 of k = 2 (at 8 from 6 p) == 0.4000 Nuclear reduced matrix element 4 <- 1 of k = 2 (at 8 from 6 p) == 0.4000 Nuclear reduced matrix element 1 <- 5 of k = 5 (at 10 from 6 p) == 0.4680 Nuclear reduced matrix element 5 <- 1 of k = 5 (at 10 from 6 p) == 0.4680 Step 4 <- 1 of k = 2 (Potl. beta = 0.04017) 1 @ 8 Beta of targ. = 0.05726 (using radius of 6.986 fm.). Step 3 <- 3 of k = 2 (Potl. beta =-0.00000) 1 @ 8 Step 5 <- 3 of k = 2 (Potl. beta = 0.00000) 1 @ 8 Step 1 <- 4 of k = 2 (Potl. beta = 0.04017) 1 @ 8 Beta of targ. = 0.05726 (using radius of 6.986 fm.). Step 4 <- 4 of k = 2 (Potl. beta =-0.00000) 1 @ 8 Step 3 <- 5 of k = 2 (Potl. beta = 0.00000) 1 @ 8 Step 5 <- 5 of k = 2 (Potl. beta =-0.00000) 1 @ 8 Step 3 <- 1 of k = 3 (Potl. beta = 0.08035) 1 @ 9 Beta of targ. = 0.11452 (using radius of 6.986 fm.). Step 1 <- 3 of k = 3 (Potl. beta = 0.08035) 1 @ 9 Beta of targ. = 0.11452 (using radius of 6.986 fm.). Step 4 <- 3 of k = 3 (Potl. beta =-0.00000) 1 @ 9 Step 3 <- 4 of k = 3 (Potl. beta =-0.00000) 1 @ 9 Step 5 <- 4 of k = 3 (Potl. beta = 0.00000) 1 @ 9 Step 4 <- 5 of k = 3 (Potl. beta = 0.00000) 1 @ 9 Step 5 <- 1 of k = 5 (Potl. beta = 0.04700) 1 @ 10 Beta of targ. = 0.06700 (using radius of 6.986 fm.). Step 4 <- 3 of k = 5 (Potl. beta = 0.00000) 1 @ 10 Step 3 <- 4 of k = 5 (Potl. beta = 0.00000) 1 @ 10 Step 5 <- 4 of k = 5 (Potl. beta =-0.00000) 1 @ 10 Step 1 <- 5 of k = 5 (Potl. beta = 0.04700) 1 @ 10 Beta of targ. = 0.06700 (using radius of 6.986 fm.). Step 4 <- 5 of k = 5 (Potl. beta =-0.00000) 1 @ 10 -------------------------------------------------------------------------------------------------------------------- 20 1=Volume 1=WS squared 11 0.0000 1.1790 0.6580 10.0000 1.0000 0.4000 0.000 602.245 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 2 2 0=Coulomb 0=CHARGE (WS) 12 207.000 17.000 1.2000 0.0000 0.0000 0.0000 0.000 611.260 0.02500 2 1=Volume 0=Woods-Saxon 13 78.2800 1.2150 0.6500 0.0000 1.1620 0.6230 0.000 611.260 2 1=Volume 1=WS squared 14 0.0000 1.1790 0.6580 10.0000 1.0000 0.4000 0.000 611.260 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 3 3 0=Coulomb 0=CHARGE (WS) 15 209.000 15.000 1.2000 0.0000 0.0000 0.0000 0.000 592.849 0.02500 3 1=Volume 0=Woods-Saxon 16 78.2800 1.2150 0.6500 0.0000 1.1620 0.6230 0.000 592.849 3 1=Volume 1=WS squared 17 0.0000 1.1790 0.6580 10.0000 1.0000 0.4000 0.000 592.849 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 0 4 0=Coulomb 0=CHARGE (WS) 18 16.000 0.000 1.2000 0.0000 0.0000 0.0000 0.000 16.000 0.02500 4 1=Volume 0=Woods-Saxon 19 60.0000 1.2000 0.6000 0.0000 0.0000 0.0000 0.000 16.000 4 3=Projtl S.O. 0=Woods-Saxon 20 6.0000 1.2000 0.6000 0.0000 0.0000 0.0000 0.000 16.000 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 0 5 0=Coulomb 0=CHARGE (WS) 21 15.000 0.000 1.2000 0.0000 0.0000 0.0000 0.000 15.000 0.02500 5 1=Volume 0=Woods-Saxon 22 60.0000 1.2000 0.6000 0.0000 0.0000 0.0000 0.000 15.000 5 3=Projtl S.O. 0=Woods-Saxon 23 6.0000 1.2000 0.6000 0.0000 0.0000 0.0000 0.000 15.000 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 0 6 0=Coulomb 0=CHARGE (WS) 24 207.000 0.000 1.2500 0.0000 0.0000 0.0000 0.000 207.000 0.02500 6 1=Volume 0=Woods-Saxon 25 60.0000 1.2500 0.6500 0.0000 0.0000 0.0000 0.000 207.000 6 3=Projtl S.O. 0=Woods-Saxon 26 7.0000 1.2500 0.6500 0.0000 0.0000 0.0000 0.000 207.000 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 0 7 0=Coulomb 0=CHARGE (WS) 27 208.000 0.000 1.2500 0.0000 0.0000 0.0000 0.000 208.000 0.02500 7 1=Volume 0=Woods-Saxon 28 60.0000 1.2800 0.7600 0.0000 0.0000 0.0000 0.000 208.000 7 3=Projtl S.O. 0=Woods-Saxon 29 5.0000 1.2800 0.7600 0.0000 0.0000 0.0000 0.000 208.000 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 4 8 0=Coulomb 0=CHARGE (WS) 30 212.000 12.000 1.2000 0.0000 0.0000 0.0000 0.000 561.957 0.02500 8 1=Volume 0=Woods-Saxon 31 78.2800 1.2150 0.6500 0.0000 1.1620 0.6230 0.000 561.957 8 1=Volume 1=WS squared 32 0.0000 1.1790 0.6580 10.0000 1.0000 0.4000 0.000 561.957 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 0 10 0=Coulomb 0=CHARGE (WS) 33 12.000 4.000 1.2500 0.0000 0.0000 0.0000 0.000 58.268 0.02500 10 1=Volume 0=Woods-Saxon 34 60.0000 1.2800 0.7600 0.0000 0.0000 0.0000 0.000 58.268 -------------------------------------------------------------------------------------------------------------------- A#1 A#2 r0c ac h @ 0 11 0=Coulomb 0=CHARGE (WS) 35 208.000 0.000 1.2500 0.0000 0.0000 0.0000 0.000 208.000 0.02500 11 1=Volume 0=Woods-Saxon 36 110.9000 1.4640 0.5000 0.0000 0.0000 0.0000 0.000 208.000 ************************************************************************************************************************************ The following SINGLE-PARTICLE FORM FACTORS are constructed : No. P1 P2 IN KIND T N L S1 IA J/S IB BIND XFER BE SC PC FIL AFRAC Adjust to Z Mass K Norm rms D0 D ANC/Gsp 1: 1 2 1 0 1 2 0.5 1 2.5 1 4 0 4.1425 1 0 0 0.0000 VR 0.9449; 0. 1.004 0.4327 1.0000 3.384 -34.9 -49.3 0.7777 3: 1 2 1 0 2 0 0.5 1 0.5 2 4 0 3.2715 1 0 0 0.0000 VR 0.9587; 0. 1.004 0.3846 1.0000 4.183 139.6 217.3 -2.7704 9: 2 1 2 0 3 1 0.5 1 0.5 0 6 0 7.3755 1 0 0 0.0000 VR 0.7613; 0. 1.001 0.5929 1.0000 6.049 -458.1-5827.3 46.2691 10: 2 1 2 0 2 3 0.5 1 2.5 0 6 0 7.9465 1 0 0 0.0000 VR 0.7547; 0. 1.001 0.6154 1.0000 5.932 41.4 474.4-18.7036 11: 2 1 2 0 3 1 0.5 1 1.5 0 6 0 8.2735 1 0 0 0.0000 VR 0.7627; 0. 1.001 0.6280 1.0000 6.006 -488.8-7943.8 63.7884 2: 3 1 1 0 1 1 0.5 1 0.5 1 5 0 12.1259 1 0 0 0.0000 VR 1.0027; 1. 0.995 0.7358 1.0000 2.652 -156.8 51.2 8.4565 5: 1 3 2 0 2 3 0.5 1 3.5 0 7 0 2.9054 1 0 0 0.0000 VR 0.9909; 1. 1.003 0.3725 1.0000 5.940 12.7 -87.3 -6.89E+08 7: 1 3 2 0 3 1 0.5 1 1.5 0 7 0 0.6840 1 0 0 0.0000 VR 0.9931; 1. 1.003 0.1807 1.0000 5.920 -36.9 32.7 5.53E+17 4: 4 1 1 0 5 0 0.0 1 0.0 0 10 0 7.1610 1 0 0 0.0000 VR 1.1642; 2. 3.995 1.0133 1.0000 4.687 -176.7-1642.9 1.03E+04 12: 1 4 2 0 10 0 0.0 1 0.0 0 11 0 1.0000 1 0 0 0.0000 VR 0.9794; 2. 4.023 0.4345 1.0000 5.985 17.9 0.0 -2.25E+83 ************************************************************************************************************************************ TWO-way COUPLING # 1 for partitions 2 <- 1 of KIND 7, 1 1 0 -1 -1 & P1,P2 = 0.0000 0.0000 : for J <= 100.5 & R < 30.0 fm. data = 1 1 1 1 1.0500, so < [17-O # 1] / [16-O # 1] * Eigen-form # 1> = 1.0500 BE = 4.142 1 data = 1 4 1 3 1.0150, so < [17-O # 4] / [16-O # 1] * Eigen-form # 3> = 1.0150 BE = 3.272 3 data = 2 1 1 9 1.5500, so < [PB-208 # 1] / [PB-207 # 1] * Eigen-form # 9> = 1.5500 BE = 7.376 9 data = 2 1 2 10 2.7900, so < [PB-208 # 1] / [PB-207 # 2] * Eigen-form # 10> = 2.7900 BE = 7.946 10 data = -2 1 3 11 1.8120, so < [PB-208 # 1] / [PB-207 # 3] * Eigen-form # 11> = 1.8120 BE = 8.274 11 KNT = 9, KNP = 1: NK,NG,loc= 1 1 1 37 T T F KNT = 10, KNP = 1: NK,NG,loc= 2 2 2 38 T T F KNT = 11, KNP = 1: NK,NG,loc= 3 3 3 39 T T F KNT = 9, KNP = 3: NK,NG,loc= 4 4 4 40 T T F KNT = 10, KNP = 3: NK,NG,loc= 5 5 5 41 T T F KNT = 11, KNP = 3: NK,NG,loc= 6 6 6 42 T T F So FINITE-RANGE TRANSFER : IP1 = 1 (PRIOR ), IP2= 1 =FULL REAL , for 6 pairs of bound states summed into 6 pairs The main coupling potential is that binding the transferred particle to the 16-O core. Using between 16-O & PB-207 the potential No. 1, and subtracting optical potential No. 1 A real*8 is 8 bytes NLL,NLN,NLO = 61 61 241 0File 11 needs RL = 14701 REAL*8 numbers, and NR = 643. i.e. 75.62 Megabytes File 11 RECL = 115680 0RECOMMENDED NON-LOCAL WIDTH IS GREATER THAN 0.58 FM., RECOMMENDED CENTRATION 0.01, after 1.40 secs. 0Relative non-local usages (rms) are 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.001 0.002 0.005 0.010 0.019 0.041 0.117 0.341 0.853 1.727 2.710 3.374 4.070 4.959 10.287 27.983 56.584 84.611 97.620 100.000 75.124 43.143 22.623 25.144 25.774 19.130 10.987 5.269 2.253 0.914 0.364 0.142 0.054 0.020 0.007 0.002 0.001 0.001 0.001 0.001 0.001 0.001 0.001 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ************************************************************************************************************************************ TWO-way COUPLING # 2 for partitions 3 <- 1 of KIND 7, 1 1 0 -1 -1 & P1,P2 = 0.0000 0.0000 : for J <= 100.5 & R < 30.0 fm. data = 1 1 1 2 1.4140, so < [16-O # 1] / [15-N # 1] * Eigen-form # 2> = 1.4140 BE = 12.126 2 data = 2 1 1 5 1.0500, so < [BI-209 # 1] / [PB-208 # 1] * Eigen-form # 5> = 1.0500 BE = 2.905 5 data = -2 2 1 7 1.0000, so < [BI-209 # 2] / [PB-208 # 1] * Eigen-form # 7> = 1.0000 BE = 0.684 7 KNT = 5, KNP = 2: NK,NG,loc= 1 1 1 37 T T F KNT = 7, KNP = 2: NK,NG,loc= 2 2 2 38 T T F So FINITE-RANGE TRANSFER : IP1 = 1 (PRIOR ), IP2= 1 =FULL REAL , for 2 pairs of bound states summed into 2 pairs The main coupling potential is that binding the transferred particle to the PB-208 core. Using between 15-N & PB-208 the potential No. 3, and subtracting optical potential No. 1 0RECOMMENDED NON-LOCAL WIDTH IS GREATER THAN 0.70 FM., RECOMMENDED CENTRATION -0.05, after 0.17 secs. 0Relative non-local usages (rms) are 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.001 0.001 0.002 0.003 0.005 0.008 0.012 0.019 0.030 0.051 0.079 0.122 0.193 0.314 0.520 0.862 1.421 2.337 3.906 6.707 11.697 20.039 32.591 49.137 67.751 84.992 96.799 100.000 93.676 78.922 59.560 39.810 23.108 11.501 5.255 3.087 2.318 1.596 0.941 0.479 0.220 0.113 0.078 0.057 0.038 0.022 0.012 0.006 0.003 0.001 0.001 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ************************************************************************************************************************************ TWO-way COUPLING # 3 for partitions 4 <- 1 of KIND 7, 1 1 0 -1 -1 & P1,P2 = 0.0000 0.0000 : for J <= 100.5 & R < 30.0 fm. data = 1 1 1 4 0.5000, so < [16-O # 1] / [12-C # 1] * Eigen-form # 4> = 0.5000 BE = 7.161 4 data = -2 1 1 12 1.3000, so < [PO-212 # 1] / [PB-208 # 1] * Eigen-form # 12> = 1.3000 BE = 1.000 12 KNT = 12, KNP = 4: NK,NG,loc= 1 1 1 37 T T F So FINITE-RANGE TRANSFER : IP1 = 1 (PRIOR ), IP2= 1 =FULL REAL , for 1 pairs of bound states summed into 1 pairs The main coupling potential is that binding the transferred particle to the PB-208 core. Using between 12-C & PB-208 the potential No. 8, and subtracting optical potential No. 1 0RECOMMENDED NON-LOCAL WIDTH IS GREATER THAN 4.55 FM., RECOMMENDED CENTRATION -0.10, after 0.08 secs. 0Relative non-local usages (rms) are 0.006 0.007 0.008 0.009 0.010 0.011 0.013 0.015 0.017 0.020 0.023 0.026 0.030 0.033 0.036 0.039 0.043 0.048 0.054 0.062 0.071 0.086 0.103 0.121 0.139 0.157 0.176 0.196 0.216 0.235 0.257 0.286 0.327 0.379 0.433 0.487 0.542 0.603 0.670 0.747 0.835 1.039 1.229 1.407 1.576 1.736 1.929 2.181 2.500 2.821 3.122 3.399 3.683 4.026 4.435 4.897 5.398 5.951 6.585 7.209 7.745 9.350 10.547 11.439 11.917 12.006 11.815 11.531 11.256 10.994 10.628 10.095 9.529 9.061 8.725 8.616 8.824 9.316 10.031 10.880 11.683 12.284 12.698 12.937 12.928 12.705 12.373 12.325 12.818 13.855 15.126 16.324 17.323 18.113 18.682 18.865 18.360 17.542 17.113 17.448 18.670 25.254 30.074 33.471 35.648 36.576 36.118 34.853 33.676 33.960 37.052 44.273 55.357 67.985 79.693 89.211 96.490 100.000 98.626 92.077 81.080 66.997 52.153 39.241 31.066 27.084 24.524 21.796 19.437 17.821 16.937 16.780 16.789 16.509 16.549 16.868 17.050 16.613 15.813 14.854 14.273 13.829 13.724 13.955 14.349 14.353 14.264 13.658 12.809 11.923 10.889 10.032 9.321 8.897 8.706 8.646 8.487 8.197 7.894 7.618 7.468 7.267 6.985 6.592 6.233 5.948 5.814 5.688 5.505 5.343 5.350 5.448 5.420 5.434 5.433 5.332 5.189 4.962 4.614 4.261 4.007 3.886 3.776 3.594 3.293 2.958 2.635 2.345 2.070 1.829 1.642 1.526 1.438 1.325 1.167 0.986 0.829 0.710 0.623 0.561 0.511 0.469 0.430 0.388 0.340 0.286 0.232 0.184 0.143 0.108 0.081 0.061 0.044 0.031 0.022 0.015 0.011 0.008 0.006 0.004 0.003 0.002 0.001 0.001 0.001 0.001 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0Binding Energies: (16-O # 1 / 12-C # 1)(BE = 7.161)-(PO-212 # 1 / PB-208 # 1)(BE = 1.000)- DISCREPANCY = 13.8390 Incoming partition 1 in excitation state # 1, Laboratory Energy given for partition 1 Nucleus 1 in Excitation pair 1 0Lab. ENERGY ranges : from 80.0000 to 0.00000 in 0 intervals from 0.00000 to 0.00000 in 0 intervals from 0.00000 to 0.00000 in 0 intervals Largest real,imaginary parts of any form factor at R= 29.75 are 4.84E-02 3.07E-44 MeV Finished all Couplings @ 1.68232894 36 Non-symmetric Hamiltonian 1*********************************************************************************************************************************** ************************************************************************************************************************************ INCOMING 16-O ; LABORATORY 16-O ENERGY = 80.000 MeV. *********************************************************************************************************************************** *********************************************************************************************************************************** NOTE: Coulomb excitation cut off below 52.672 deg by JTMAX, and below 24.285 deg by Rmax Allocate arrays for 17 channels, of which 17 need wfs. ###################################################################################################################### # # # Total SPIN and PARITY = 0.0 +, 17 channels, 3 in 1st block. Rmin & Coul turning = 0.0 12.7 fm. # # # ###################################################################################################################### C Projectl Target # EX. (L Proj) J + Targ = Jtotal E-cm Re K Re Eta RM*K CH 1 16-O PB-208 # 1: I 0 0.0 0.0 0.0 0.0 74.28682 7.26568 46.19448 217.9703 0.48188 0.31169 1 1 1 1 2 16-O PB-208 # 2: 3 3.0 0.0 0.0 0.0 68.15682 6.95945 48.22712 208.7834 -0.37446 0.44799 1 2 1 1 3 16-O PB-208 # 3: 3 0.0 3.0 3.0 0.0 71.67682 7.13690 47.02801 214.1069 -0.34558 0.46315 1 1 1 3 4 16-O PB-208 # 4: 2 0.0 2.0 2.0 0.0 70.21682 7.06384 47.51441 211.9151 0.55233 -0.17773 1 1 1 4 5 16-O PB-208 # 5: 5 0.0 5.0 5.0 0.0 71.08682 7.10746 47.22277 213.2239 0.29610 0.49747 1 1 1 5 6 17-O PB-207 # 1: 3 2.5 0.5 0.5 0.0 71.05382 7.30776 48.57608 219.2327 -0.57655 0.05183 2 1 2 1 7 17-O PB-207 # 2: 1 2.5 2.5 2.5 0.0 70.48282 7.27833 48.77245 218.3500 -0.28941 0.50235 2 1 2 2 8 17-O PB-207 # 2: 3 2.5 2.5 2.5 0.0 70.48282 7.27833 48.77245 218.3500 -0.25037 0.52296 2 1 2 2 9 17-O PB-207 # 2: 5 2.5 2.5 2.5 0.0 70.48282 7.27833 48.77245 218.3500 -0.17680 0.55230 2 1 2 2 10 17-O PB-207 # 3: 1 2.5 1.5 1.5 0.0 70.15582 7.26143 48.88598 217.8429 0.04146 0.57882 2 1 2 3 11 17-O PB-207 # 3: 3 2.5 1.5 1.5 0.0 70.15582 7.26143 48.88598 217.8429 0.08520 0.57407 2 1 2 3 12 17-O PB-207 # 4: 1 0.5 0.5 0.5 0.0 70.18282 7.26283 48.87658 217.8849 0.01300 0.58011 2 4 2 1 13 17-O PB-207 # 5: 3 0.5 2.5 2.5 0.0 69.61182 7.23322 49.07663 216.9967 0.52754 0.24411 2 4 2 2 14 17-O PB-207 # 6: 1 0.5 1.5 1.5 0.0 69.28482 7.21621 49.19231 216.4864 0.57954 -0.05117 2 4 2 3 15 15-N BI-209 # 1: 4 0.5 3.5 3.5 0.0 65.06632 6.60066 42.43548 198.0198 0.31661 -0.48023 3 1 3 1 16 15-N BI-209 # 2: 2 0.5 1.5 1.5 0.0 62.84492 6.48700 43.17896 194.6101 0.09214 0.57162 3 1 3 2 17 12-C PO-212 # 1: 0 0.0 0.0 0.0 0.0 54.28682 5.43126 36.30432 162.9377 -0.50500 -0.28413 4 1 4 1 S-matrix 1 = 0.58240 0.61374 for L= 0, J= 0.0 channel on core I = 0.0 from L= 0, Acc. loss = 1.3 D. Elastic phase shift 1 = 23.250 4.788 deg. for the L = 0, J = 0.0 channel. Psi(EL) renorm. by 1.17E+00-1.54E-01, Conv = 0.68319 % Psi(EL) renorm. by 1.11E+00-1.01E-01, Conv = 0.27536 % Final S-matrices ( 0.0+) at 6 after 6 accurate to 0.0074 % of J= 100.0 unitarity: 0.32766 +i* 0.43127, 0.0 0.32765523 0.43126726i: elastic S-matrix @@ 0.28 0 0 F 0 Reaction Xsec 0.0+/ 0 @ 1 = 0.421 , Out: 0.000# 4.737/ 7.192/ 1.677/ 3.400/ 8.099/ 9.302/ 2.049/ 2.696/ Xsec 1.268/ 0.984/ 0.027 9.597/ 0.078 0.265f 33.674c Allocate arrays for 41 channels, of which 41 need wfs. Total SPIN, PARITY = 1.0 -, 41 chs, 5 cc. Rmin & Coul turning = 0.1 12.7 S-matrix 1 = 0.58761 0.61291 for L= 1, J= 1.0 channel on core I = 0.0 from L= 1, Acc. loss = 1.3 D. Elastic phase shift 1 = 23.104 4.687 deg. for the L = 1, J = 1.0 channel. Psi(EL) renorm. by 1.17E+00-1.52E-01, Conv = 0.95379 % Psi(EL) renorm. by 1.11E+00-9.91E-02, Conv = 0.38590 % Final S-matrices ( 1.0-) at 7 after 7 accurate to 0.0028 % of J= 100.0 unitarity: 0.33047 +i* 0.43432, 1.0 0.33046769 0.43432155i: elastic S-matrix @@ 0.90 0 0 F 0 Reaction Xsec 1.0-/ 1 @ 1 = 1.254 , Out: 0.000# 0.014 0.021 5.055/ 0.010 0.024 0.028 6.097/ 8.077/ Xsec 3.784/ 2.945/ 0.080 0.029 0.235 0.786f 98.046c Allocate arrays for 60 channels, of which 60 need wfs. Total SPIN, PARITY = 2.0 +, 60 chs, 7 cc. Rmin & Coul turning = 0.2 12.7 S-matrix 1 = 0.59791 0.61107 for L= 2, J= 2.0 channel on core I = 0.0 from L= 2, Acc. loss = 1.3 D. Elastic phase shift 1 = 22.812 4.490 deg. for the L = 2, J = 2.0 channel. Psi(EL) renorm. by 1.16E+00-1.50E-01, Conv = 1.21914 % Psi(EL) renorm. by 1.10E+00-9.61E-02, Conv = 0.49679 % Final S-matrices ( 2.0+) at 7 after 7 accurate to 0.0030 % of J= 100.0 unitarity: 0.33629 +i* 0.43948, 2.0 0.33628525 0.43948258i: elastic S-matrix @@ 1.29 0 0 F 0 Reaction Xsec 2.0+/ 2 @ 1 = 2.064 , Out: 0.000# 0.024 0.035 8.328/ 0.017 0.041 0.047 0.010 0.013 Xsec 6.320/ 4.911/ 0.135 0.048 0.391 1.283f 153.358c Allocate arrays for 72 channels, of which 72 need wfs. Total SPIN, PARITY = 3.0 -, 72 chs, 9 cc. Rmin & Coul turning = 0.3 12.7 S-matrix 1 = 0.61311 0.60789 for L= 3, J= 3.0 channel on core I = 0.0 from L= 3, Acc. loss = 1.2 D. Elastic phase shift 1 = 22.378 4.208 deg. for the L = 3, J = 3.0 channel. Psi(EL) renorm. by 1.15E+00-1.46E-01, Conv = 1.47613 % Psi(EL) renorm. by 1.09E+00-9.16E-02, Conv = 0.60726 % Final S-matrices ( 3.0-) at 7 after 7 accurate to 0.0043 % of J= 100.0 unitarity: 0.34568 +i* 0.44792, 3.0 0.34568101 0.44792074i: elastic S-matrix @@ 1.47 0 0 F 0 Reaction Xsec 3.0-/ 3 @ 1 = 2.832 , Out: 0.000# 0.033 0.048 0.011 0.024 0.057 0.067 0.015 0.019 Xsec 8.917/ 6.899/ 0.192 0.066 0.546 1.738f 195.138c Allocate arrays for 77 channels, of which 77 need wfs. Total SPIN, PARITY = 4.0 +, 77 chs, 9 cc. Rmin & Coul turning = 0.4 12.7 S-matrix 1 = 0.63282 0.60289 for L= 4, J= 4.0 channel on core I = 0.0 from L= 4, Acc. loss = 1.2 D. Elastic phase shift 1 = 21.806 3.857 deg. for the L = 4, J = 4.0 channel. Psi(EL) renorm. by 1.13E+00-1.40E-01, Conv = 1.72096 % Psi(EL) renorm. by 1.08E+00-8.55E-02, Conv = 0.71548 % Final S-matrices ( 4.0+) at 7 after 7 accurate to 0.0062 % of J= 100.0 unitarity: 0.35947 +i* 0.45828, 4.0 0.35947436 0.45828420i: elastic S-matrix @@ 1.45 0 0 F 0 Reaction Xsec 4.0+/ 4 @ 1 = 3.539 , Out: 0.000# 0.042 0.060 0.014 0.030 0.075 0.088 0.019 0.024 Xsec 0.012 8.900/ 0.252 0.085 0.696 2.132f 220.595c Allocate arrays for 79 channels, of which 79 need wfs. Total SPIN, PARITY = 5.0 -, 79 chs, 9 cc. Rmin & Coul turning = 0.5 12.8 S-matrix 1 = 0.65653 0.59556 for L= 5, J= 5.0 channel on core I = 0.0 from L= 5, Acc. loss = 1.2 D. Elastic phase shift 1 = 21.106 3.454 deg. for the L = 5, J = 5.0 channel. Psi(EL) renorm. by 1.11E+00-1.32E-01, Conv = 1.94916 % Psi(EL) renorm. by 1.07E+00-7.82E-02, Conv = 0.81846 % Final S-matrices ( 5.0-) at 6 after 6 accurate to 0.0071 % of J= 100.0 unitarity: 0.37731 +i* 0.46966, 5.0 0.37731284 0.46966077i: elastic S-matrix @@ 1.27 0 0 F 0 Reaction Xsec 5.0-/ 5 @ 1 = 4.170 , Out: 0.000# 0.051 0.069 0.017 0.037 0.094 0.112 0.024 0.030 Xsec 0.014 0.011 0.315 0.103 0.842 2.453f 227.789c Total SPIN, PARITY = 6.0 +, 79 chs, 9 cc. Rmin & Coul turning = 0.6 12.8 S-matrix 1 = 0.68352 0.58536 for L= 6, J= 6.0 channel on core I = 0.0 from L= 6, Acc. loss = 1.1 D. Elastic phase shift 1 = 20.288 3.021 deg. for the L = 6, J = 6.0 channel. Psi(EL) renorm. by 1.10E+00-1.22E-01, Conv = 2.15570 % Final S-matrices ( 6.0+) at 6 after 6 accurate to 0.0093 % of J= 100.0 unitarity: 0.40180 +i* 0.48215, 6.0 0.40180254 0.48214644i: elastic S-matrix @@ 1.28 0 0 F 0 Reaction Xsec 6.0+/ 6 @ 1 = 4.689 , Out: 0.000# 0.060 0.076 0.019 0.042 0.113 0.136 0.029 0.036 Xsec 0.017 0.013 0.376 0.120 0.975 2.676f 219.795c Total SPIN, PARITY = 7.0 -, 79 chs, 9 cc. Rmin & Coul turning = 0.7 12.8 S-matrix 1 = 0.71288 0.57187 for L= 7, J= 7.0 channel on core I = 0.0 from L= 7, Acc. loss = 1.0 D. Elastic phase shift 1 = 19.368 2.579 deg. for the L = 7, J = 7.0 channel. Psi(EL) renorm. by 1.08E+00-1.11E-01, Conv = 2.33546 % Psi(EL) renorm. by 1.15E+00-1.29E-01, Conv = 0.02224 % Psi(EL) renorm. by 1.15E+00-1.24E-01, Conv = 0.03198 % Psi(EL) renorm. by 3.59E-01-5.24E-02, Conv = 0.02928 % Psi(EL) renorm. by 3.60E-01-5.27E-02, Conv = 0.01103 % Psi(EL) renorm. by -4.65E-02 5.90E-02, Conv = 0.00905 % Final S-matrices ( 7.0-) at 12 after 12 accurate to 0.0091 % of J= 100.0 unitarity: 0.42575 +i* 0.49188, 7.0 0.42575485 0.49187596i: elastic S-matrix @@ 2.54 0 0 F 0 Reaction Xsec 7.0-/ 7 @ 1 = 5.149 , Out: 0.000# 0.067 0.082 0.021 0.047 0.130 0.158 0.033 0.040 Xsec 0.019 0.015 0.430 0.133 1.082 2.891f********c Total SPIN, PARITY = 8.0 +, 79 chs, 9 cc. Rmin & Coul turning = 1.0 12.8 S-matrix 1 = 0.74359 0.55483 for L= 8, J= 8.0 channel on core I = 0.0 from L= 8, Acc. loss = 0.8 D. Elastic phase shift 1 = 18.364 2.148 deg. for the L = 8, J = 8.0 channel. Psi(EL) renorm. by 1.07E+00-9.92E-02, Conv = 2.48374 % Psi(EL) renorm. by 9.31E-01-1.44E-01, Conv = 0.03331 % Psi(EL) renorm. by 9.36E-01-1.43E-01, Conv = 0.04622 % Psi(EL) renorm. by 3.59E-01 2.85E-01, Conv = 0.02372 % Psi(EL) renorm. by 3.60E-01 2.85E-01, Conv = 0.01097 % Psi(EL) renorm. by -8.26E-02-5.34E-02, Conv = 0.00894 % Final S-matrices ( 8.0+) at 12 after 12 accurate to 0.0089 % of J= 100.0 unitarity: 0.45886 +i* 0.50496, 8.0 0.45886293 0.50496386i: elastic S-matrix @@ 2.12 0 0 F 0 Reaction Xsec 8.0+/ 8 @ 1 = 5.407 , Out: 0.000# 0.075 0.085 0.022 0.052 0.150 0.186 0.038 0.045 Xsec 0.022 0.017 0.489 0.146 1.193 2.886f********c Total SPIN, PARITY = 9.0 -, 79 chs, 9 cc. Rmin & Coul turning = 1.2 12.8 S-matrix 1 = 0.77455 0.53424 for L= 9, J= 9.0 channel on core I = 0.0 from L= 9, Acc. loss = 0.3 D. Elastic phase shift 1 = 17.298 1.745 deg. for the L = 9, J = 9.0 channel. Psi(EL) renorm. by 1.05E+00-8.71E-02, Conv = 2.59683 % Psi(EL) renorm. by 8.69E-01 6.88E-03, Conv = 0.02977 % Psi(EL) renorm. by 8.73E-01 3.32E-03, Conv = 0.04830 % Psi(EL) renorm. by 1.26E-01 1.29E+00, Conv = 0.01424 % Psi(EL) renorm. by 1.27E-01 1.29E+00, Conv = 0.00928 % Final S-matrices ( 9.0-) at 11 after 11 accurate to 0.0093 % of J= 100.0 unitarity: 0.49890 +i* 0.51310, 9.0 0.49890082 0.51309659i: elastic S-matrix @@ 2.04 0 0 F 0 Reaction Xsec 9.0-/ 9 @ 1 = 5.516 , Out: 0.000# 0.081 0.083 0.022 0.055 0.170 0.213 0.044 0.051 Xsec 0.025 0.019 0.540 0.157 1.268 2.786f********c Total SPIN, PARITY = 10.0 +, 79 chs, 9 cc. Rmin & Coul turning = 1.6 12.9 S-matrix 1 = 0.80470 0.51036 for L= 10, J= 10.0 channel on core I = 0.0 from L= 10, Acc. loss = 0.6 D. Elastic phase shift 1 = 16.192 1.382 deg. for the L = 10, J = 10.0 channel. Psi(EL) renorm. by 9.67E-01 1.15E-01, Conv = 0.01858 % Psi(EL) renorm. by 9.67E-01 1.10E-01, Conv = 0.04838 % Psi(EL) renorm. by 7.78E-01-1.32E+00, Conv = 0.02234 % Psi(EL) renorm. by 7.79E-01-1.32E+00, Conv = 0.01462 % Psi(EL) renorm. by 1.56E-01 3.05E-02, Conv = 0.01354 % Psi(EL) renorm. by 1.56E-01 3.08E-02, Conv = 0.02054 % Psi(EL) renorm. by -3.81E-02 2.23E-03, Conv = 0.02146 % Psi(EL) renorm. by -3.81E-02 2.25E-03, Conv = 0.01053 % Psi(EL) renorm. by 8.12E-03-1.66E-03, Conv = 0.00957 % Final S-matrices ( 10.0+) at 16 after 16 accurate to 0.0096 % of J= 100.0 unitarity: 0.54032 +i* 0.51532, 10.0 0.54032269 0.51531792i: elastic S-matrix @@ 2.94 0 0 F 0 Reaction Xsec 10.0+/10 @ 1 = 5.530 , Out: 0.000# 0.086 0.079 0.022 0.057 0.188 0.239 0.049 0.055 Xsec 0.028 0.020 0.569 0.163 1.308 2.669f4053.833c Total SPIN, PARITY = 11.0 -, 79 chs, 9 cc. Rmin & Coul turning = 1.9 12.9 S-matrix 1 = 0.83312 0.48372 for L= 11, J= 11.0 channel on core I = 0.0 from L= 11, Acc. loss = 1.2 D. Elastic phase shift 1 = 15.070 1.069 deg. for the L = 11, J = 11.0 channel. Psi(EL) renorm. by 1.09E+00 3.91E-02, Conv = 0.01940 % Psi(EL) renorm. by 6.64E-01-2.58E-01, Conv = 0.02717 % Psi(EL) renorm. by 6.65E-01-2.58E-01, Conv = 0.01710 % Psi(EL) renorm. by 5.42E-02 2.95E-01, Conv = 0.01427 % Psi(EL) renorm. by 5.39E-02 2.96E-01, Conv = 0.02166 % Psi(EL) renorm. by -2.74E-03-6.45E-02, Conv = 0.01761 % Psi(EL) renorm. by -2.77E-03-6.45E-02, Conv = 0.00831 % Final S-matrices ( 11.0-) at 15 after 15 accurate to 0.0083 % of J= 100.0 unitarity: 0.58532 +i* 0.51527, 11.0 0.58532370 0.51527295i: elastic S-matrix @@ 2.87 0 0 F 0 Reaction Xsec 11.0-/11 @ 1 = 5.364 , Out: 0.000# 0.089 0.073 0.021 0.059 0.206 0.266 0.054 0.059 Xsec 0.030 0.022 0.594 0.167 1.336 2.388f9331.908c Total SPIN, PARITY = 12.0 +, 79 chs, 9 cc. Rmin & Coul turning = 2.2 12.9 S-matrix 1 = 0.85914 0.45501 for L= 12, J= 12.0 channel on core I = 0.0 from L= 12, Acc. loss = 1.6 D. Elastic phase shift 1 = 13.953 0.808 deg. for the L = 12, J = 12.0 channel. Psi(EL) renorm. by 7.32E-01 8.23E-02, Conv = 0.02424 % Psi(EL) renorm. by 7.32E-01 8.19E-02, Conv = 0.01127 % Psi(EL) renorm. by -1.07E+00-6.49E-02, Conv = 0.01073 % Psi(EL) renorm. by -1.07E+00-6.43E-02, Conv = 0.01767 % Psi(EL) renorm. by 1.07E-01-1.41E-02, Conv = 0.00941 % Final S-matrices ( 12.0+) at 14 after 14 accurate to 0.0094 % of J= 100.0 unitarity: 0.63311 +i* 0.50931, 12.0 0.63310582 0.50930743i: elastic S-matrix @@ 2.72 0 0 F 0 Reaction Xsec 12.0+/12 @ 1 = 5.055 , Out: 0.000# 0.091 0.064 0.020 0.059 0.223 0.290 0.058 0.063 Xsec 0.032 0.023 0.605 0.168 1.330 2.030f9290.710c Total SPIN, PARITY = 13.0 -, 79 chs, 9 cc. Rmin & Coul turning = 2.5 13.0 S-matrix 1 = 0.88232 0.42502 for L= 13, J= 13.0 channel on core I = 0.0 from L= 13, Acc. loss = 2.3 D. Elastic phase shift 1 = 12.860 0.598 deg. for the L = 13, J = 13.0 channel. Psi(EL) renorm. by 1.01E+00 2.41E-01, Conv = 0.01345 % Psi(EL) renorm. by 1.01E+00 2.41E-01, Conv = 0.00842 % Final S-matrices ( 13.0-) at 11 after 11 accurate to 0.0084 % of J= 100.0 unitarity: 0.67966 +i* 0.49586, 13.0 0.67965607 0.49585507i: elastic S-matrix @@ 2.11 0 0 F 0 Reaction Xsec 13.0-/13 @ 1 = 4.695 , Out: 0.000# 0.091 0.054 0.017 0.057 0.236 0.312 0.063 0.066 Xsec 0.034 0.025 0.598 0.165 1.290 1.687f3277.550c Total SPIN, PARITY = 14.0 +, 79 chs, 9 cc. Rmin & Coul turning = 2.8 13.0 S-matrix 1 = 0.90250 0.39454 for L= 14, J= 14.0 channel on core I = 0.0 from L= 14, Acc. loss = 2.1 D. Elastic phase shift 1 = 11.807 0.434 deg. for the L = 14, J = 14.0 channel. Psi(EL) renorm. by 1.15E+00-3.11E-02, Conv = 0.00902 % Final S-matrices ( 14.0+) at 10 after 10 accurate to 0.0090 % of J= 100.0 unitarity: 0.72506 +i* 0.47695, 14.0 0.72506103 0.47694943i: elastic S-matrix @@ 1.98 0 0 F 0 Reaction Xsec 14.0+/14 @ 1 = 4.259 , Out: 0.000# 0.089 0.043 0.015 0.054 0.247 0.330 0.066 0.068 Xsec 0.036 0.026 0.579 0.160 1.228 1.318f1606.029c Total SPIN, PARITY = 15.0 -, 79 chs, 9 cc. Rmin & Coul turning = 3.1 13.1 S-matrix 1 = 0.91973 0.36427 for L= 15, J= 15.0 channel on core I = 0.0 from L= 15, Acc. loss = 1.8 D. Elastic phase shift 1 = 10.803 0.310 deg. for the L = 15, J = 15.0 channel. Final S-matrices ( 15.0-) at 11 after 11 accurate to 0.0060 % of J= 100.0 unitarity: 0.76580 +i* 0.45291, 15.0 0.76579549 0.45290924i: elastic S-matrix @@ 2.24 0 0 F 0 Reaction Xsec 15.0-/15 @ 1 = 3.845 , Out: 0.000# 0.086 0.033 0.012 0.050 0.255 0.343 0.069 0.069 Xsec 0.037 0.026 0.545 0.151 1.144 1.024f 446.368c Total SPIN, PARITY = 16.0 +, 79 chs, 9 cc. Rmin & Coul turning = 3.4 13.1 S-matrix 1 = 0.93420 0.33476 for L= 16, J= 16.0 channel on core I = 0.0 from L= 16, Acc. loss = 1.8 D. Elastic phase shift 1 = 9.857 0.219 deg. for the L = 16, J = 16.0 channel. Final S-matrices ( 16.0+) at 7 after 7 accurate to 0.0086 % of J= 100.0 unitarity: 0.80310 +i* 0.42593, 16.0 0.80310414 0.42592938i: elastic S-matrix @@ 1.31 0 0 F 0 Reaction Xsec 16.0+/16 @ 1 = 3.409 , Out: 0.000# 0.081 0.025 9.682/ 0.046 0.261 0.353 0.072 0.070 Xsec 0.038 0.027 0.510 0.142 1.049 0.727f 3.461c Total SPIN, PARITY = 17.0 -, 79 chs, 9 cc. Rmin & Coul turning = 3.6 13.2 S-matrix 1 = 0.94623 0.30645 for L= 17, J= 17.0 channel on core I = 0.0 from L= 17, Acc. loss = 1.9 D. Elastic phase shift 1 = 8.973 0.155 deg. for the L = 17, J = 17.0 channel. Final S-matrices ( 17.0-) at 8 after 8 accurate to 0.0097 % of J= 100.0 unitarity: 0.83393 +i* 0.39707, 17.0 0.83392507 0.39707300i: elastic S-matrix @@ 1.51 0 0 F 0 Reaction Xsec 17.0-/17 @ 1 = 3.060 , Out: 0.000# 0.075 0.018 7.412/ 0.041 0.262 0.358 0.073 0.069 Xsec 0.038 0.027 0.462 0.131 0.943 0.555f 9.426c Total SPIN, PARITY = 18.0 +, 79 chs, 9 cc. Rmin & Coul turning = 3.9 13.2 S-matrix 1 = 0.95614 0.27961 for L= 18, J= 18.0 channel on core I = 0.0 from L= 18, Acc. loss = 2.0 D. Elastic phase shift 1 = 8.150 0.110 deg. for the L = 18, J = 18.0 channel. Final S-matrices ( 18.0+) at 9 after 9 accurate to 0.0083 % of J= 100.0 unitarity: 0.86150 +i* 0.36793, 18.0 0.86149541 0.36792846i: elastic S-matrix @@ 1.75 0 0 F 0 Reaction Xsec 18.0+/18 @ 1 = 2.696 , Out: 0.000# 0.069 0.013 5.442/ 0.037 0.264 0.362 0.074 0.069 Xsec 0.038 0.027 0.418 0.121 0.841 0.357f 3.728c Total SPIN, PARITY = 19.0 -, 79 chs, 9 cc. Rmin & Coul turning = 4.2 13.3 S-matrix 1 = 0.96424 0.25440 for L= 19, J= 19.0 channel on core I = 0.0 from L= 19, Acc. loss = 2.1 D. Elastic phase shift 1 = 7.390 0.079 deg. for the L = 19, J = 19.0 channel. Final S-matrices ( 19.0-) at 6 after 6 accurate to 0.0084 % of J= 100.0 unitarity: 0.88454 +i* 0.33877, 19.0 0.88454184 0.33876545i: elastic S-matrix @@ 1.04 0 0 F 0 Reaction Xsec 19.0-/19 @ 1 = 2.386 , Out: 0.000# 0.062 0.011 3.823/ 0.032 0.263 0.361 0.075 0.068 Xsec 0.038 0.027 0.374 0.110 0.736 0.227f 0.430c Total SPIN, PARITY = 20.0 +, 79 chs, 9 cc. Rmin & Coul turning = 4.4 13.3 S-matrix 1 = 0.97086 0.23089 for L= 20, J= 20.0 channel on core I = 0.0 from L= 20, Acc. loss = 2.2 D. Elastic phase shift 1 = 6.689 0.059 deg. for the L = 20, J = 20.0 channel. Final S-matrices ( 20.0+) at 5 after 5 accurate to 0.0072 % of J= 100.0 unitarity: 0.90361 +i* 0.30986, 20.0 0.90360685 0.30985811i: elastic S-matrix @@ 0.84 0 0 F 0 Reaction Xsec 20.0+/20 @ 1 = 2.135 , Out: 0.000# 0.055 0.010 2.513/ 0.028 0.261 0.359 0.075 0.067 Xsec 0.037 0.026 0.333 0.099 0.637 0.145f 0.140c Total SPIN, PARITY = 21.0 -, 79 chs, 9 cc. Rmin & Coul turning = 4.7 13.4 S-matrix 1 = 0.97623 0.20911 for L= 21, J= 21.0 channel on core I = 0.0 from L= 21, Acc. loss = 2.3 D. Elastic phase shift 1 = 6.045 0.047 deg. for the L = 21, J = 21.0 channel. Final S-matrices ( 21.0-) at 5 after 5 accurate to 0.0050 % of J= 100.0 unitarity: 0.91947 +i* 0.28258, 21.0 0.91947408 0.28257720i: elastic S-matrix @@ 0.84 0 0 F 0 Reaction Xsec 21.0-/21 @ 1 = 1.912 , Out: 0.000# 0.049 0.012 1.535/ 0.023 0.257 0.354 0.075 0.065 Xsec 0.036 0.026 0.295 0.089 0.543 0.086f 0.081c Total SPIN, PARITY = 22.0 +, 79 chs, 9 cc. Rmin & Coul turning = 4.9 13.4 S-matrix 1 = 0.98060 0.18901 for L= 22, J= 22.0 channel on core I = 0.0 from L= 22, Acc. loss = 2.2 D. Elastic phase shift 1 = 5.455 0.039 deg. for the L = 22, J = 22.0 channel. Final S-matrices ( 22.0+) at 5 after 5 accurate to 0.0036 % of J= 100.0 unitarity: 0.93252 +i* 0.25693, 22.0 0.93251624 0.25692710i: elastic S-matrix @@ 0.85 0 0 F 0 Reaction Xsec 22.0+/22 @ 1 = 1.725 , Out: 0.000# 0.043 0.015 0.858/ 0.020 0.252 0.347 0.074 0.064 Xsec 0.035 0.025 0.260 0.080 0.457 0.052f 0.048c Total SPIN, PARITY = 23.0 -, 79 chs, 9 cc. Rmin & Coul turning = 5.1 13.5 S-matrix 1 = 0.98414 0.17053 for L= 23, J= 23.0 channel on core I = 0.0 from L= 23, Acc. loss = 2.8 D. Elastic phase shift 1 = 4.915 0.034 deg. for the L = 23, J = 23.0 channel. Final S-matrices ( 23.0-) at 5 after 5 accurate to 0.0026 % of J= 100.0 unitarity: 0.94329 +i* 0.23307, 23.0 0.94329307 0.23307397i: elastic S-matrix @@ 0.81 0 0 F 0 Reaction Xsec 23.0-/23 @ 1 = 1.563 , Out: 0.000# 0.037 0.020 0.475/ 0.016 0.246 0.339 0.073 0.062 Xsec 0.034 0.025 0.229 0.071 0.381 0.030f 0.028c Total SPIN, PARITY = 24.0 +, 79 chs, 9 cc. Rmin & Coul turning = 5.4 13.6 S-matrix 1 = 0.98701 0.15360 for L= 24, J= 24.0 channel on core I = 0.0 from L= 24, Acc. loss = 3.8 D. Elastic phase shift 1 = 4.423 0.032 deg. for the L = 24, J = 24.0 channel. Final S-matrices ( 24.0+) at 5 after 5 accurate to 0.0019 % of J= 100.0 unitarity: 0.95223 +i* 0.21100, 24.0 0.95222525 0.21100264i: elastic S-matrix @@ 0.79 0 0 F 0 Reaction Xsec 24.0+/24 @ 1 = 1.421 , Out: 0.000# 0.032 0.026 0.387/ 0.013 0.240 0.329 0.071 0.059 Xsec 0.033 0.024 0.201 0.063 0.313 0.017f 0.016c Total SPIN, PARITY = 25.0 -, 79 chs, 9 cc. Rmin & Coul turning = 5.6 13.6 S-matrix 1 = 0.98933 0.13812 for L= 25, J= 25.0 channel on core I = 0.0 from L= 25, Acc. loss = 3.5 D. Elastic phase shift 1 = 3.974 0.031 deg. for the L = 25, J = 25.0 channel. Final S-matrices ( 25.0-) at 5 after 5 accurate to 0.0013 % of J= 100.0 unitarity: 0.95962 +i* 0.19067, 25.0 0.95961729 0.19066585i: elastic S-matrix @@ 0.79 0 0 F 0 Reaction Xsec 25.0-/25 @ 1 = 1.298 , Out: 0.000# 0.027 0.033 0.575/ 0.011 0.233 0.318 0.070 0.057 Xsec 0.032 0.023 0.176 0.055 0.254 0.009f 0.008c Total SPIN, PARITY = 26.0 +, 79 chs, 9 cc. Rmin & Coul turning = 5.8 13.7 S-matrix 1 = 0.99120 0.12400 for L= 26, J= 26.0 channel on core I = 0.0 from L= 26, Acc. loss = 3.5 D. Elastic phase shift 1 = 3.565 0.031 deg. for the L = 26, J = 26.0 channel. Final S-matrices ( 26.0+) at 5 after 5 accurate to 0.0009 % of J= 100.0 unitarity: 0.96573 +i* 0.17202, 26.0 0.96573440 0.17201706i: elastic S-matrix @@ 0.80 0 0 F 0 Reaction Xsec 26.0+/26 @ 1 = 1.191 , Out: 0.000# 0.023 0.040 0.985/ 8.648/ 0.226 0.306 0.068 0.055 Xsec 0.031 0.022 0.154 0.049 0.204 0.004f 0.005c Total SPIN, PARITY = 27.0 -, 79 chs, 9 cc. Rmin & Coul turning = 6.0 13.8 S-matrix 1 = 0.99270 0.11116 for L= 27, J= 27.0 channel on core I = 0.0 from L= 27, Acc. loss = 3.6 D. Elastic phase shift 1 = 3.195 0.031 deg. for the L = 27, J = 27.0 channel. Final S-matrices ( 27.0-) at 5 after 5 accurate to 0.0007 % of J= 100.0 unitarity: 0.97081 +i* 0.15498, 27.0 0.97080560 0.15497564i: elastic S-matrix @@ 0.83 0 0 F 0 Reaction Xsec 27.0-/27 @ 1 = 1.097 , Out: 0.000# 0.019 0.048 1.537/ 6.805/ 0.218 0.294 0.066 0.052 Xsec 0.029 0.021 0.135 0.042 0.162 0.002f 0.002c Total SPIN, PARITY = 28.0 +, 79 chs, 9 cc. Rmin & Coul turning = 6.2 13.8 S-matrix 1 = 0.99390 0.09950 for L= 28, J= 28.0 channel on core I = 0.0 from L= 28, Acc. loss = 3.6 D. Elastic phase shift 1 = 2.859 0.032 deg. for the L = 28, J = 28.0 channel. Final S-matrices ( 28.0+) at 5 after 5 accurate to 0.0005 % of J= 100.0 unitarity: 0.97502 +i* 0.13945, 28.0 0.97501614 0.13944858i: elastic S-matrix @@ 0.87 0 0 F 0 Reaction Xsec 28.0+/28 @ 1 = 1.014 , Out: 0.000# 0.015 0.057 2.154/ 5.271/ 0.210 0.281 0.064 0.050 Xsec 0.028 0.020 0.117 0.037 0.127 0.001f 0.001c Total SPIN, PARITY = 29.0 -, 79 chs, 9 cc. Rmin & Coul turning = 6.4 13.9 S-matrix 1 = 0.99487 0.08895 for L= 29, J= 29.0 channel on core I = 0.0 from L= 29, Acc. loss = 3.7 D. Elastic phase shift 1 = 2.555 0.033 deg. for the L = 29, J = 29.0 channel. Final S-matrices ( 29.0-) at 5 after 5 accurate to 0.0004 % of J= 100.0 unitarity: 0.97852 +i* 0.12534, 29.0 0.97851631 0.12533816i: elastic S-matrix @@ 0.89 0 0 F 0 Reaction Xsec 29.0-/29 @ 1 = 0.941 , Out: 0.000# 0.013 0.065 2.795/ 4.011/ 0.201 0.268 0.062 0.047 Xsec 0.026 0.019 0.102 0.032 0.098 0.000f 0.000c Total SPIN, PARITY = 30.0 +, 79 chs, 9 cc. Rmin & Coul turning = 6.6 14.0 S-matrix 1 = 0.99563 0.07941 for L= 30, J= 30.0 channel on core I = 0.0 from L= 30, Acc. loss = 3.6 D. Elastic phase shift 1 = 2.280 0.035 deg. for the L = 30, J = 30.0 channel. Final S-matrices ( 30.0+) at 5 after 5 accurate to 0.0003 % of J= 100.0 unitarity: 0.98143 +i* 0.11255, 30.0 0.98143062 0.11254532i: elastic S-matrix @@ 0.89 0 0 F 0 Reaction Xsec 30.0+/30 @ 1 = 0.876 , Out: 0.000# 0.010 0.074 3.476/ 2.994/ 0.193 0.254 0.060 0.045 Xsec 0.025 0.018 0.088 0.028 0.075 0.000f 0.000c Total SPIN, PARITY = 31.0 -, 79 chs, 9 cc. Rmin & Coul turning = 6.8 14.1 S-matrix 1 = 0.99624 0.07081 for L= 31, J= 31.0 channel on core I = 0.0 from L= 31, Acc. loss = 3.4 D. Elastic phase shift 1 = 2.033 0.036 deg. for the L = 31, J = 31.0 channel. Final S-matrices ( 31.0-) at 5 after 5 accurate to 0.0002 % of J= 100.0 unitarity: 0.98386 +i* 0.10098, 31.0 0.98386311 0.10097543i: elastic S-matrix @@ 0.88 0 0 F 0 Reaction Xsec 31.0-/31 @ 1 = 0.818 , Out: 0.000# 8.065/ 0.082 4.235/ 2.185/ 0.184 0.241 0.057 0.042 Xsec 0.024 0.017 0.076 0.024 0.057 0.000f 0.000c Total SPIN, PARITY = 32.0 +, 79 chs, 9 cc. Rmin & Coul turning = 7.0 14.1 S-matrix 1 = 0.99672 0.06307 for L= 32, J= 32.0 channel on core I = 0.0 from L= 32, Acc. loss = 4.2 D. Elastic phase shift 1 = 1.810 0.037 deg. for the L = 32, J = 32.0 channel. Final S-matrices ( 32.0+) at 5 after 5 accurate to 0.0002 % of J= 100.0 unitarity: 0.98590 +i* 0.09053, 32.0 0.98590121 0.09053388i: elastic S-matrix @@ 0.91 0 0 F 0 Reaction Xsec 32.0+/32 @ 1 = 0.766 , Out: 0.000# 6.383/ 0.089 5.083/ 1.554/ 0.175 0.227 0.055 0.039 Xsec 0.022 0.016 0.066 0.020 0.043 -0.000f 0.000c Total SPIN, PARITY = 33.0 -, 79 chs, 9 cc. Rmin & Coul turning = 7.2 14.2 S-matrix 1 = 0.99711 0.05611 for L= 33, J= 33.0 channel on core I = 0.0 from L= 33, Acc. loss = 4.0 D. Elastic phase shift 1 = 1.610 0.038 deg. for the L = 33, J = 33.0 channel. Final S-matrices ( 33.0-) at 4 after 4 accurate to 0.0095 % of J= 100.0 unitarity: 0.98762 +i* 0.08113, 33.0 0.98761663 0.08112621i: elastic S-matrix @@ 0.67 0 0 F 0 Reaction Xsec 33.0-/33 @ 1 = 0.719 , Out: 0.000# 4.995/ 0.097 5.954/ 1.072/ 0.166 0.214 0.052 0.037 Xsec 0.021 0.015 0.057 0.017 0.032 0.000f 0.000c Total SPIN, PARITY = 34.0 +, 79 chs, 9 cc. Rmin & Coul turning = 7.4 14.3 S-matrix 1 = 0.99741 0.04987 for L= 34, J= 34.0 channel on core I = 0.0 from L= 34, Acc. loss = 3.8 D. Elastic phase shift 1 = 1.431 0.038 deg. for the L = 34, J = 34.0 channel. Final S-matrices ( 34.0+) at 4 after 4 accurate to 0.0080 % of J= 100.0 unitarity: 0.98906 +i* 0.07267, 34.0 0.98906479 0.07266783i: elastic S-matrix @@ 0.67 0 0 F 0 Reaction Xsec 34.0+/34 @ 1 = 0.676 , Out: 0.000# 3.855/ 0.103 6.742/ 0.714/ 0.157 0.200 0.050 0.034 Xsec 0.019 0.014 0.049 0.015 0.023 0.000f 0.000c Total SPIN, PARITY = 35.0 -, 79 chs, 9 cc. Rmin & Coul turning = 7.6 14.4 S-matrix 1 = 0.99765 0.04429 for L= 35, J= 35.0 channel on core I = 0.0 from L= 35, Acc. loss = 3.8 D. Elastic phase shift 1 = 1.271 0.039 deg. for the L = 35, J = 35.0 channel. Final S-matrices ( 35.0-) at 4 after 4 accurate to 0.0068 % of J= 100.0 unitarity: 0.99029 +i* 0.06507, 35.0 0.99029464 0.06507499i: elastic S-matrix @@ 0.66 0 0 F 0 Reaction Xsec 35.0-/35 @ 1 = 0.637 , Out: 0.000# 2.926/ 0.110 7.352/ 0.456/ 0.148 0.187 0.047 0.032 Xsec 0.018 0.013 0.042 0.013 0.017 -0.000f 0.000c Total SPIN, PARITY = 36.0 +, 79 chs, 9 cc. Rmin & Coul turning = 7.7 14.5 S-matrix 1 = 0.99784 0.03931 for L= 36, J= 36.0 channel on core I = 0.0 from L= 36, Acc. loss = 3.8 D. Elastic phase shift 1 = 1.128 0.040 deg. for the L = 36, J = 36.0 channel. Final S-matrices ( 36.0+) at 4 after 4 accurate to 0.0057 % of J= 100.0 unitarity: 0.99135 +i* 0.05827, 36.0 0.99134550 0.05826923i: elastic S-matrix @@ 0.67 0 0 F 0 Reaction Xsec 36.0+/36 @ 1 = 0.601 , Out: 0.000# 2.185/ 0.115 7.788/ 0.278/ 0.139 0.174 0.044 0.030 Xsec 0.017 0.012 0.036 0.011 0.012 -0.000f 0.000c Total SPIN, PARITY = 37.0 -, 79 chs, 9 cc. Rmin & Coul turning = 7.9 14.5 S-matrix 1 = 0.99800 0.03486 for L= 37, J= 37.0 channel on core I = 0.0 from L= 37, Acc. loss = 3.7 D. Elastic phase shift 1 = 1.000 0.040 deg. for the L = 37, J = 37.0 channel. Final S-matrices ( 37.0-) at 4 after 4 accurate to 0.0049 % of J= 100.0 unitarity: 0.99225 +i* 0.05218, 37.0 0.99224859 0.05217818i: elastic S-matrix @@ 0.67 0 0 F 0 Reaction Xsec 37.0-/37 @ 1 = 0.568 , Out: 0.000# 1.609/ 0.121 8.162/ 0.164/ 0.131 0.162 0.042 0.028 Xsec 0.016 0.011 0.030 9.024/ 8.679/ -0.000f 0.000c Total SPIN, PARITY = 38.0 +, 79 chs, 9 cc. Rmin & Coul turning = 8.1 14.6 S-matrix 1 = 0.99812 0.03090 for L= 38, J= 38.0 channel on core I = 0.0 from L= 38, Acc. loss = 3.5 D. Elastic phase shift 1 = 0.887 0.040 deg. for the L = 38, J = 38.0 channel. Final S-matrices ( 38.0+) at 4 after 4 accurate to 0.0042 % of J= 100.0 unitarity: 0.99303 +i* 0.04673, 38.0 0.99303072 0.04673196i: elastic S-matrix @@ 0.57 0 0 F 0 Reaction Xsec 38.0+/38 @ 1 = 0.536 , Out: 0.000# 1.174/ 0.125 8.596/ 0.098/ 0.122 0.150 0.039 0.026 Xsec 0.014 0.011 0.026 7.584/ 6.144/ -0.000f 0.000c Total SPIN, PARITY = 39.0 -, 79 chs, 9 cc. Rmin & Coul turning = 8.2 14.7 S-matrix 1 = 0.99823 0.02739 for L= 39, J= 39.0 channel on core I = 0.0 from L= 39, Acc. loss = 3.3 D. Elastic phase shift 1 = 0.786 0.040 deg. for the L = 39, J = 39.0 channel. Final S-matrices ( 39.0-) at 4 after 4 accurate to 0.0036 % of J= 100.0 unitarity: 0.99371 +i* 0.04187, 39.0 0.99371093 0.04186924i: elastic S-matrix @@ 0.59 0 0 F 0 Reaction Xsec 39.0-/39 @ 1 = 0.507 , Out: 0.000# 0.848/ 0.128 9.113/ 0.069/ 0.114 0.138 0.037 0.024 Xsec 0.013 9.761/ 0.022 6.354/ 4.316/ -0.000f 0.000c Total SPIN, PARITY = 40.0 +, 79 chs, 9 cc. Rmin & Coul turning = 8.4 14.8 S-matrix 1 = 0.99832 0.02426 for L= 40, J= 40.0 channel on core I = 0.0 from L= 40, Acc. loss = 2.9 D. Elastic phase shift 1 = 0.696 0.040 deg. for the L = 40, J = 40.0 channel. Final S-matrices ( 40.0+) at 4 after 4 accurate to 0.0031 % of J= 100.0 unitarity: 0.99431 +i* 0.03753, 40.0 0.99430581 0.03753193i: elastic S-matrix @@ 0.60 0 0 F 0 Reaction Xsec 40.0+/40 @ 1 = 0.480 , Out: 0.000# 0.601/ 0.131 9.590/ 0.065/ 0.106 0.127 0.034 0.022 Xsec 0.012 9.007/ 0.018 5.308/ 3.010/ -0.000f 0.000c Total SPIN, PARITY = 41.0 -, 79 chs, 9 cc. Rmin & Coul turning = 8.6 14.9 S-matrix 1 = 0.99839 0.02149 for L= 41, J= 41.0 channel on core I = 0.0 from L= 41, Acc. loss = 2.6 D. Elastic phase shift 1 = 0.617 0.040 deg. for the L = 41, J = 41.0 channel. Final S-matrices ( 41.0-) at 4 after 4 accurate to 0.0026 % of J= 100.0 unitarity: 0.99483 +i* 0.03367, 41.0 0.99482855 0.03366769i: elastic S-matrix @@ 0.64 0 0 F 0 Reaction Xsec 41.0-/41 @ 1 = 0.454 , Out: 0.000# 0.416/ 0.134 9.862/ 0.080/ 0.099 0.117 0.032 0.020 Xsec 0.011 8.283/ 0.016 4.421/ 2.086/ -0.000f 0.000c Total SPIN, PARITY = 42.0 +, 79 chs, 9 cc. Rmin & Coul turning = 8.8 15.0 S-matrix 1 = 0.99845 0.01904 for L= 42, J= 42.0 channel on core I = 0.0 from L= 42, Acc. loss = 2.2 D. Elastic phase shift 1 = 0.546 0.039 deg. for the L = 42, J = 42.0 channel. Final S-matrices ( 42.0+) at 4 after 4 accurate to 0.0023 % of J= 100.0 unitarity: 0.99529 +i* 0.03023, 42.0 0.99529035 0.03022816i: elastic S-matrix @@ 0.64 0 0 F 0 Reaction Xsec 42.0+/42 @ 1 = 0.429 , Out: 0.000# 0.282/ 0.136 9.878/ 0.107/ 0.092 0.107 0.030 0.019 Xsec 0.010 7.592/ 0.013 3.673/ 1.436/ -0.000f 0.000c Total SPIN, PARITY = 43.0 -, 79 chs, 9 cc. Rmin & Coul turning = 8.9 15.1 S-matrix 1 = 0.99851 0.01687 for L= 43, J= 43.0 channel on core I = 0.0 from L= 43, Acc. loss = 2.0 D. Elastic phase shift 1 = 0.484 0.039 deg. for the L = 43, J = 43.0 channel. Final S-matrices ( 43.0-) at 4 after 4 accurate to 0.0020 % of J= 100.0 unitarity: 0.99570 +i* 0.02717, 43.0 0.99570026 0.02716963i: elastic S-matrix @@ 0.65 0 0 F 0 Reaction Xsec 43.0-/43 @ 1 = 0.406 , Out: 0.000# 0.194/ 0.138 9.762/ 0.141/ 0.085 0.097 0.027 0.017 Xsec 9.344/ 6.939/ 0.011 3.043/ 0.983/ -0.000f 0.000c Total SPIN, PARITY = 44.0 +, 79 chs, 9 cc. Rmin & Coul turning = 9.1 15.2 S-matrix 1 = 0.99856 0.01496 for L= 44, J= 44.0 channel on core I = 0.0 from L= 44, Acc. loss = 1.0 D. Elastic phase shift 1 = 0.429 0.038 deg. for the L = 44, J = 44.0 channel. Final S-matrices ( 44.0+) at 4 after 4 accurate to 0.0017 % of J= 100.0 unitarity: 0.99607 +i* 0.02445, 44.0 0.99606627 0.02445120i: elastic S-matrix @@ 0.62 0 0 F 0 Reaction Xsec 44.0+/44 @ 1 = 0.384 , Out: 0.000# 0.143/ 0.139 9.717/ 0.177/ 0.078 0.089 0.025 0.016 Xsec 8.516/ 6.327/ 9.274/ 2.515/ 0.669/ -0.000f 0.000c Total SPIN, PARITY = 45.0 -, 79 chs, 9 cc. Rmin & Coul turning = 9.2 15.3 S-matrix 1 = 0.99861 0.01328 for L= 45, J= 45.0 channel on core I = 0.0 from L= 45, Acc. loss = 1.7 D. Elastic phase shift 1 = 0.381 0.037 deg. for the L = 45, J = 45.0 channel. Final S-matrices ( 45.0-) at 4 after 4 accurate to 0.0015 % of J= 100.0 unitarity: 0.99639 +i* 0.02204, 45.0 0.99639394 0.02203666i: elastic S-matrix @@ 0.62 0 0 F 0 Reaction Xsec 45.0-/45 @ 1 = 0.364 , Out: 0.000# 0.115/ 0.139 9.825/ 0.214/ 0.072 0.081 0.023 0.014 Xsec 7.745/ 5.757/ 7.767/ 2.074/ 0.452/ -0.000f 0.000c Total SPIN, PARITY = 46.0 +, 79 chs, 9 cc. Rmin & Coul turning = 9.4 15.4 S-matrix 1 = 0.99866 0.01179 for L= 46, J= 46.0 channel on core I = 0.0 from L= 46, Acc. loss = 1.4 D. Elastic phase shift 1 = 0.338 0.036 deg. for the L = 46, J = 46.0 channel. Final S-matrices ( 46.0+) at 4 after 4 accurate to 0.0013 % of J= 100.0 unitarity: 0.99669 +i* 0.01989, 46.0 0.99668856 0.01989201i: elastic S-matrix @@ 0.59 0 0 F 0 Reaction Xsec 46.0+/46 @ 1 = 0.344 , Out: 0.000# 0.098/ 0.139 9.963/ 0.249/ 0.066 0.073 0.021 0.013 Xsec 7.027/ 5.230/ 6.493/ 1.706/ 0.303/ -0.000f 0.000c Total SPIN, PARITY = 47.0 -, 79 chs, 9 cc. Rmin & Coul turning = 9.6 15.5 S-matrix 1 = 0.99871 0.01047 for L= 47, J= 47.0 channel on core I = 0.0 from L= 47, Acc. loss = 1.2 D. Elastic phase shift 1 = 0.300 0.036 deg. for the L = 47, J = 47.0 channel. Final S-matrices ( 47.0-) at 4 after 4 accurate to 0.0012 % of J= 100.0 unitarity: 0.99695 +i* 0.01799, 47.0 0.99695304 0.01798858i: elastic S-matrix @@ 0.60 0 0 F 0 Reaction Xsec 47.0-/47 @ 1 = 0.326 , Out: 0.000# 0.090/ 0.139 9.922/ 0.281/ 0.060 0.066 0.020 0.012 Xsec 6.364/ 4.745/ 5.417/ 1.400/ 0.202/ -0.000f 0.000c Total SPIN, PARITY = 48.0 +, 79 chs, 9 cc. Rmin & Coul turning = 9.7 15.6 S-matrix 1 = 0.99875 0.00932 for L= 48, J= 48.0 channel on core I = 0.0 from L= 48, Acc. loss = 1.0 D. Elastic phase shift 1 = 0.267 0.035 deg. for the L = 48, J = 48.0 channel. Final S-matrices ( 48.0+) at 4 after 4 accurate to 0.0010 % of J= 100.0 unitarity: 0.99719 +i* 0.01630, 48.0 0.99719177 0.01629913i: elastic S-matrix @@ 0.60 0 0 F 0 Reaction Xsec 48.0+/48 @ 1 = 0.308 , Out: 0.000# 0.092/ 0.139 9.623/ 0.310/ 0.055 0.060 0.018 0.011 Xsec 5.752/ 4.300/ 4.511/ 1.146/ 0.134/ -0.000f 0.000c Total SPIN, PARITY = 49.0 -, 79 chs, 9 cc. Rmin & Coul turning = 9.9 15.7 S-matrix 1 = 0.99879 0.00830 for L= 49, J= 49.0 channel on core I = 0.0 from L= 49, Acc. loss = 0.8 D. Elastic phase shift 1 = 0.238 0.034 deg. for the L = 49, J = 49.0 channel. Final S-matrices ( 49.0-) at 4 after 4 accurate to 0.0009 % of J= 100.0 unitarity: 0.99741 +i* 0.01480, 49.0 0.99740770 0.01480050i: elastic S-matrix @@ 0.58 0 0 F 0 Reaction Xsec 49.0-/49 @ 1 = 0.292 , Out: 0.000# 0.105/ 0.138 9.217/ 0.334/ 0.050 0.054 0.016 0.010 Xsec 5.189/ 3.891/ 3.749/ 0.936/ 0.088/ 0.000f 0.000c Total SPIN, PARITY = 50.0 +, 79 chs, 9 cc. Rmin & Coul turning = 10.0 15.8 S-matrix 1 = 0.99883 0.00741 for L= 50, J= 50.0 channel on core I = 0.0 from L= 50, Acc. loss = 1.2 D. Elastic phase shift 1 = 0.213 0.033 deg. for the L = 50, J = 50.0 channel. Final S-matrices ( 50.0+) at 4 after 4 accurate to 0.0008 % of J= 100.0 unitarity: 0.99760 +i* 0.01347, 50.0 0.99760401 0.01347030i: elastic S-matrix @@ 0.58 0 0 F 0 Reaction Xsec 50.0+/50 @ 1 = 0.277 , Out: 0.000# 0.123/ 0.137 8.936/ 0.354/ 0.046 0.048 0.015 9.112/ Xsec 4.673/ 3.516/ 3.110/ 0.763/ 0.057/ 0.000f 0.000c Total SPIN, PARITY = 51.0 -, 79 chs, 9 cc. Rmin & Coul turning = 10.2 15.9 S-matrix 1 = 0.99887 0.00663 for L= 51, J= 51.0 channel on core I = 0.0 from L= 51, Acc. loss = 0.6 D. Elastic phase shift 1 = 0.190 0.032 deg. for the L = 51, J = 51.0 channel. Final S-matrices ( 51.0-) at 4 after 4 accurate to 0.0007 % of J= 100.0 unitarity: 0.99778 +i* 0.01229, 51.0 0.99778295 0.01228859i: elastic S-matrix @@ 0.61 0 0 F 0 Reaction Xsec 51.0-/51 @ 1 = 0.262 , Out: 0.000# 0.138/ 0.135 8.849/ 0.369/ 0.042 0.043 0.014 8.261/ Xsec 4.200/ 3.172/ 2.576/ 0.620/ 0.037/ 0.000f 0.000c Total SPIN, PARITY = 52.0 +, 79 chs, 9 cc. Rmin & Coul turning = 10.3 16.0 S-matrix 1 = 0.99891 0.00594 for L= 52, J= 52.0 channel on core I = 0.0 from L= 52, Acc. loss = 0.4 D. Elastic phase shift 1 = 0.170 0.031 deg. for the L = 52, J = 52.0 channel. Final S-matrices ( 52.0+) at 4 after 4 accurate to 0.0007 % of J= 100.0 unitarity: 0.99795 +i* 0.01124, 52.0 0.99794575 0.01123773i: elastic S-matrix @@ 0.60 0 0 F 0 Reaction Xsec 52.0+/52 @ 1 = 0.249 , Out: 0.000# 0.146/ 0.133 8.790/ 0.380/ 0.038 0.039 0.012 7.475/ Xsec 3.768/ 2.857/ 2.129/ 0.503/ 0.024/ 0.000f 0.000c Total SPIN, PARITY = 53.0 -, 79 chs, 9 cc. Rmin & Coul turning = 10.5 16.1 S-matrix 1 = 0.99895 0.00533 for L= 53, J= 53.0 channel on core I = 0.0 from L= 53, Acc. loss = 0.3 D. Elastic phase shift 1 = 0.153 0.030 deg. for the L = 53, J = 53.0 channel. Final S-matrices ( 53.0-) at 4 after 4 accurate to 0.0006 % of J= 100.0 unitarity: 0.99809 +i* 0.01030, 53.0 0.99809348 0.01030272i: elastic S-matrix @@ 0.59 0 0 F 0 Reaction Xsec 53.0-/53 @ 1 = 0.236 , Out: 0.000# 0.152/ 0.132 8.540/ 0.388/ 0.034 0.034 0.011 6.751/ Xsec 3.375/ 2.568/ 1.757/ 0.408/ 0.015/ 0.000f 0.000c Total SPIN, PARITY = 54.0 +, 79 chs, 9 cc. Rmin & Coul turning = 10.6 16.2 S-matrix 1 = 0.99898 0.00480 for L= 54, J= 54.0 channel on core I = 0.0 from L= 54, Acc. loss = 0.2 D. Elastic phase shift 1 = 0.138 0.029 deg. for the L = 54, J = 54.0 channel. Final S-matrices ( 54.0+) at 4 after 4 accurate to 0.0005 % of J= 100.0 unitarity: 0.99823 +i* 0.00947, 54.0 0.99822761 0.00947092i: elastic S-matrix @@ 0.58 0 0 F 0 Reaction Xsec 54.0+/54 @ 1 = 0.224 , Out: 0.000# 0.163/ 0.130 8.074/ 0.392/ 0.031 0.031 0.010 6.087/ Xsec 3.017/ 2.306/ 1.448/ 0.329/ 9.694# 0.000f 0.000c Total SPIN, PARITY = 55.0 -, 79 chs, 9 cc. Rmin & Coul turning = 10.8 16.3 S-matrix 1 = 0.99902 0.00433 for L= 55, J= 55.0 channel on core I = 0.0 from L= 55, Acc. loss = 0.1 D. Elastic phase shift 1 = 0.124 0.028 deg. for the L = 55, J = 55.0 channel. Final S-matrices ( 55.0-) at 4 after 4 accurate to 0.0005 % of J= 100.0 unitarity: 0.99835 +i* 0.00873, 55.0 0.99835048 0.00873016i: elastic S-matrix @@ 0.56 0 0 F 0 Reaction Xsec 55.0-/55 @ 1 = 0.213 , Out: 0.000# 0.180/ 0.128 7.595/ 0.393/ 0.028 0.027 9.232/ 5.482/ Xsec 2.692/ 2.067/ 1.191/ 0.266/ 6.263# 0.000f 0.000c Total SPIN, PARITY = 56.0 +, 79 chs, 9 cc. Rmin & Coul turning = 10.9 16.4 S-matrix 1 = 0.99905 0.00392 for L= 56, J= 56.0 channel on core I = 0.0 from L= 56, Acc. loss = 0.2 D. Elastic phase shift 1 = 0.112 0.027 deg. for the L = 56, J = 56.0 channel. Final S-matrices ( 56.0+) at 4 after 4 accurate to 0.0004 % of J= 100.0 unitarity: 0.99846 +i* 0.00807, 56.0 0.99846381 0.00806892i: elastic S-matrix @@ 0.57 0 0 F 0 Reaction Xsec 56.0+/56 @ 1 = 0.202 , Out: 0.000# 0.193/ 0.126 7.311/ 0.391/ 0.025 0.024 8.323/ 4.932/ Xsec 2.399/ 1.850/ 0.979/ 0.214/ 4.091# 0.000f 0.000c Total SPIN, PARITY = 57.0 -, 79 chs, 9 cc. Rmin & Coul turning = 11.1 16.5 S-matrix 1 = 0.99909 0.00355 for L= 57, J= 57.0 channel on core I = 0.0 from L= 57, Acc. loss = 0.1 D. Elastic phase shift 1 = 0.102 0.026 deg. for the L = 57, J = 57.0 channel. Final S-matrices ( 57.0-) at 4 after 4 accurate to 0.0004 % of J= 100.0 unitarity: 0.99857 +i* 0.00748, 57.0 0.99856834 0.00747671i: elastic S-matrix @@ 0.56 0 0 F 0 Reaction Xsec 57.0-/57 @ 1 = 0.192 , Out: 0.000# 0.196/ 0.123 7.197/ 0.386/ 0.023 0.022 7.485/ 4.434/ Xsec 2.135/ 1.654/ 0.804/ 0.172/ 2.713# 0.000f 0.000c Total SPIN, PARITY = 58.0 +, 79 chs, 9 cc. Rmin & Coul turning = 11.2 16.6 S-matrix 1 = 0.99912 0.00323 for L= 58, J= 58.0 channel on core I = 0.0 from L= 58, Acc. loss = 0.1 D. Elastic phase shift 1 = 0.093 0.025 deg. for the L = 58, J = 58.0 channel. Final S-matrices ( 58.0+) at 4 after 4 accurate to 0.0004 % of J= 100.0 unitarity: 0.99866 +i* 0.00695, 58.0 0.99866374 0.00694505i: elastic S-matrix @@ 0.57 0 0 F 0 Reaction Xsec 58.0+/58 @ 1 = 0.183 , Out: 0.000# 0.192/ 0.120 7.034/ 0.380/ 0.021 0.019 6.717/ 3.981/ Xsec 1.897/ 1.476/ 0.659/ 0.138/ 1.829# 0.000f 0.000c Total SPIN, PARITY = 59.0 -, 79 chs, 9 cc. Rmin & Coul turning = 11.4 16.7 S-matrix 1 = 0.99916 0.00294 for L= 59, J= 59.0 channel on core I = 0.0 from L= 59, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.084 0.024 deg. for the L = 59, J = 59.0 channel. Final S-matrices ( 59.0-) at 4 after 4 accurate to 0.0003 % of J= 100.0 unitarity: 0.99875 +i* 0.00647, 59.0 0.99875025 0.00646778i: elastic S-matrix @@ 0.56 0 0 F 0 Reaction Xsec 59.0-/59 @ 1 = 0.174 , Out: 0.000# 0.190/ 0.118 6.665/ 0.372/ 0.018 0.017 6.017/ 3.570/ Xsec 1.683/ 1.317/ 0.539/ 0.111/ 1.252# 0.000f 0.000c Total SPIN, PARITY = 60.0 +, 79 chs, 9 cc. Rmin & Coul turning = 11.5 16.8 S-matrix 1 = 0.99919 0.00269 for L= 60, J= 60.0 channel on core I = 0.0 from L= 60, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.077 0.023 deg. for the L = 60, J = 60.0 channel. Final S-matrices ( 60.0+) at 4 after 4 accurate to 0.0003 % of J= 100.0 unitarity: 0.99883 +i* 0.00604, 60.0 0.99882934 0.00603921i: elastic S-matrix @@ 0.56 0 0 F 0 Reaction Xsec 60.0+/60 @ 1 = 0.166 , Out: 0.000# 0.196/ 0.116 6.174/ 0.363/ 0.016 0.015 5.382/ 3.197/ Xsec 1.491/ 1.173/ 0.441/ 0.089/ 0.866# 0.000f 0.000c Total SPIN, PARITY = 61.0 -, 79 chs, 9 cc. Rmin & Coul turning = 11.7 16.9 S-matrix 1 = 0.99922 0.00247 for L= 61, J= 61.0 channel on core I = 0.0 from L= 61, Acc. loss = 0.1 D. Elastic phase shift 1 = 0.071 0.022 deg. for the L = 61, J = 61.0 channel. Final S-matrices ( 61.0-) at 4 after 4 accurate to 0.0003 % of J= 100.0 unitarity: 0.99890 +i* 0.00565, 61.0 0.99890288 0.00565320i: elastic S-matrix @@ 0.54 0 0 F 0 Reaction Xsec 61.0-/61 @ 1 = 0.158 , Out: 0.000# 0.203/ 0.114 5.793/ 0.353/ 0.015 0.013 4.809/ 2.858/ Xsec 1.320/ 1.043/ 0.360/ 0.071/ 0.603# 0.000f 0.000c Total SPIN, PARITY = 62.0 +, 79 chs, 9 cc. Rmin & Coul turning = 11.8 17.1 S-matrix 1 = 0.99925 0.00227 for L= 62, J= 62.0 channel on core I = 0.0 from L= 62, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.065 0.021 deg. for the L = 62, J = 62.0 channel. Final S-matrices ( 62.0+) at 4 after 4 accurate to 0.0003 % of J= 100.0 unitarity: 0.99897 +i* 0.00530, 62.0 0.99897156 0.00530354i: elastic S-matrix @@ 0.53 0 0 F 0 Reaction Xsec 62.0+/62 @ 1 = 0.151 , Out: 0.000# 0.202/ 0.111 5.621/ 0.342/ 0.013 0.012 4.293/ 2.550/ Xsec 1.166/ 0.926/ 0.294/ 0.057/ 0.418# 0.000f 0.000c Total SPIN, PARITY = 63.0 -, 79 chs, 9 cc. Rmin & Coul turning = 12.0 17.2 S-matrix 1 = 0.99928 0.00209 for L= 63, J= 63.0 channel on core I = 0.0 from L= 63, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.060 0.021 deg. for the L = 63, J = 63.0 channel. Final S-matrices ( 63.0-) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99903 +i* 0.00499, 63.0 0.99903467 0.00498536i: elastic S-matrix @@ 0.53 0 0 F 0 Reaction Xsec 63.0-/63 @ 1 = 0.144 , Out: 0.000# 0.191/ 0.108 5.519/ 0.330/ 0.012 0.010 3.829/ 2.271/ Xsec 1.029/ 0.821/ 0.239/ 0.045/ 0.287# 0.000f 0.000c Total SPIN, PARITY = 64.0 +, 79 chs, 9 cc. Rmin & Coul turning = 12.1 17.3 S-matrix 1 = 0.99931 0.00193 for L= 64, J= 64.0 channel on core I = 0.0 from L= 64, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.055 0.020 deg. for the L = 64, J = 64.0 channel. Final S-matrices ( 64.0+) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99909 +i* 0.00470, 64.0 0.99909173 0.00469575i: elastic S-matrix @@ 0.53 0 0 F 0 Reaction Xsec 64.0+/64 @ 1 = 0.138 , Out: 0.000# 0.180/ 0.105 5.284/ 0.318/ 0.010 8.933/ 3.411/ 2.020/ Xsec 0.907/ 0.727/ 0.195/ 0.036/ 0.193# 0.000f 0.000c Total SPIN, PARITY = 65.0 -, 79 chs, 9 cc. Rmin & Coul turning = 12.2 17.4 S-matrix 1 = 0.99934 0.00179 for L= 65, J= 65.0 channel on core I = 0.0 from L= 65, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.051 0.019 deg. for the L = 65, J = 65.0 channel. Final S-matrices ( 65.0-) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99914 +i* 0.00443, 65.0 0.99914360 0.00443274i: elastic S-matrix @@ 0.46 0 0 F 0 Reaction Xsec 65.0-/65 @ 1 = 0.132 , Out: 0.000# 0.176/ 0.103 4.884/ 0.306/ 9.333/ 7.848/ 3.036/ 1.794/ Xsec 0.798/ 0.643/ 0.158/ 0.029/ 0.127# 0.000f 0.000c Total SPIN, PARITY = 66.0 +, 79 chs, 9 cc. Rmin & Coul turning = 12.4 17.5 S-matrix 1 = 0.99936 0.00166 for L= 66, J= 66.0 channel on core I = 0.0 from L= 66, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.048 0.018 deg. for the L = 66, J = 66.0 channel. Final S-matrices ( 66.0+) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99919 +i* 0.00419, 66.0 0.99919226 0.00419332i: elastic S-matrix @@ 0.49 0 0 F 0 Reaction Xsec 66.0+/66 @ 1 = 0.126 , Out: 0.000# 0.179/ 0.101 4.497/ 0.294/ 8.304/ 6.883/ 2.699/ 1.592/ Xsec 0.701/ 0.567/ 0.128/ 0.023/ 0.081# 0.000f 0.000c Total SPIN, PARITY = 67.0 -, 79 chs, 9 cc. Rmin & Coul turning = 12.5 17.6 S-matrix 1 = 0.99939 0.00155 for L= 67, J= 67.0 channel on core I = 0.0 from L= 67, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.044 0.018 deg. for the L = 67, J = 67.0 channel. Final S-matrices ( 67.0-) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99924 +i* 0.00397, 67.0 0.99923872 0.00397352i: elastic S-matrix @@ 0.48 0 0 F 0 Reaction Xsec 67.0-/67 @ 1 = 0.121 , Out: 0.000# 0.177/ 0.098 4.291/ 0.282/ 7.378/ 6.028/ 2.395/ 1.412/ Xsec 0.616/ 0.501/ 0.104/ 0.018/ 0.049# 0.000f 0.000c Total SPIN, PARITY = 68.0 +, 79 chs, 9 cc. Rmin & Coul turning = 12.7 17.7 S-matrix 1 = 0.99941 0.00144 for L= 68, J= 68.0 channel on core I = 0.0 from L= 68, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.041 0.017 deg. for the L = 68, J = 68.0 channel. Final S-matrices ( 68.0+) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99928 +i* 0.00377, 68.0 0.99928223 0.00376996i: elastic S-matrix @@ 0.48 0 0 F 0 Reaction Xsec 68.0+/68 @ 1 = 0.116 , Out: 0.000# 0.165/ 0.095 4.223/ 0.269/ 6.545/ 5.271/ 2.121/ 1.252/ Xsec 0.541/ 0.441/ 0.084/ 0.014/ 0.029# 0.000f 0.000c Total SPIN, PARITY = 69.0 -, 79 chs, 9 cc. Rmin & Coul turning = 12.8 17.8 S-matrix 1 = 0.99944 0.00135 for L= 69, J= 69.0 channel on core I = 0.0 from L= 69, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.039 0.016 deg. for the L = 69, J = 69.0 channel. Final S-matrices ( 69.0-) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99932 +i* 0.00358, 69.0 0.99932150 0.00358137i: elastic S-matrix @@ 0.48 0 0 F 0 Reaction Xsec 69.0-/69 @ 1 = 0.111 , Out: 0.000# 0.149/ 0.092 4.110/ 0.257/ 5.796/ 4.600/ 1.875/ 1.109/ Xsec 0.474/ 0.389/ 0.068/ 0.011/ 0.016# 0.000f 0.000c Total SPIN, PARITY = 70.0 +, 79 chs, 9 cc. Rmin & Coul turning = 13.0 18.0 S-matrix 1 = 0.99946 0.00126 for L= 70, J= 70.0 channel on core I = 0.0 from L= 70, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.036 0.015 deg. for the L = 70, J = 70.0 channel. Final S-matrices ( 70.0+) at 4 after 4 accurate to 0.0002 % of J= 100.0 unitarity: 0.99936 +i* 0.00341, 70.0 0.99935685 0.00340769i: elastic S-matrix @@ 0.47 0 0 F 0 Reaction Xsec 70.0+/70 @ 1 = 0.107 , Out: 0.000# 0.140/ 0.090 3.842/ 0.245/ 5.123/ 4.008/ 1.654/ 0.981/ Xsec 0.415/ 0.342/ 0.055/ 8.900# 0.009# 0.000f 0.000c Total SPIN, PARITY = 71.0 -, 79 chs, 9 cc. Rmin & Coul turning = 13.1 18.1 S-matrix 1 = 0.99948 0.00119 for L= 71, J= 71.0 channel on core I = 0.0 from L= 71, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.034 0.015 deg. for the L = 71, J = 71.0 channel. Final S-matrices ( 71.0-) at 4 after 4 accurate to 0.0001 % of J= 100.0 unitarity: 0.99939 +i* 0.00325, 71.0 0.99939009 0.00324790i: elastic S-matrix @@ 0.46 0 0 F 0 Reaction Xsec 71.0-/71 @ 1 = 0.103 , Out: 0.000# 0.140/ 0.088 3.510/ 0.234/ 4.523/ 3.492/ 1.456/ 0.867/ Xsec 0.363/ 0.301/ 0.045/ 7.026# 0.005# 0.000f 0.000c Total SPIN, PARITY = 72.0 +, 79 chs, 9 cc. Rmin & Coul turning = 13.2 18.2 S-matrix 1 = 0.99950 0.00112 for L= 72, J= 72.0 channel on core I = 0.0 from L= 72, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.032 0.014 deg. for the L = 72, J = 72.0 channel. Final S-matrices ( 72.0+) at 4 after 4 accurate to 0.0001 % of J= 100.0 unitarity: 0.99942 +i* 0.00310, 72.0 0.99942261 0.00309929i: elastic S-matrix @@ 0.47 0 0 F 0 Reaction Xsec 72.0+/72 @ 1 = 0.099 , Out: 0.000# 0.138/ 0.085 3.293/ 0.223/ 3.988/ 3.038/ 1.281/ 0.766/ Xsec 0.318/ 0.264/ 0.036/ 5.541# 0.002# 0.000f 0.000c Total SPIN, PARITY = 73.0 -, 79 chs, 9 cc. Rmin & Coul turning = 13.4 18.3 S-matrix 1 = 0.99953 0.00105 for L= 73, J= 73.0 channel on core I = 0.0 from L= 73, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.030 0.014 deg. for the L = 73, J = 73.0 channel. Final S-matrices ( 73.0-) at 4 after 4 accurate to 0.0001 % of J= 100.0 unitarity: 0.99945 +i* 0.00296, 73.0 0.99945367 0.00295926i: elastic S-matrix @@ 0.47 0 0 F 0 Reaction Xsec 73.0-/73 @ 1 = 0.095 , Out: 0.000# 0.128/ 0.083 3.238/ 0.212/ 3.514/ 2.642/ 1.126/ 0.676/ Xsec 0.278/ 0.232/ 0.029/ 4.365# 0.001# 0.000f 0.000c Total SPIN, PARITY = 74.0 +, 79 chs, 9 cc. Rmin & Coul turning = 13.5 18.4 S-matrix 1 = 0.99955 0.00099 for L= 74, J= 74.0 channel on core I = 0.0 from L= 74, Acc. loss = 0.0 D. Elastic phase shift 1 = 0.028 0.013 deg. for the L = 74, J = 74.0 channel. Final S-matrices ( 74.0+) at 4 after 4 accurate to 0.0001 % of J= 100.0 unitarity: 0.99948 +i* 0.00283, 74.0 0.99948162 0.00282717i: elastic S-matrix @@ 0.46 0 0 F 0 Reaction Xsec 74.0+/74 @ 1 = 0.091 , Out: 0.000# 0.113/ 0.080 3.222/ 0.201/ 3.095/ 2.294/ 0.989/ 0.597/ Xsec 0.242/ 0.203/ 0.023/ 3.436# 0.000# 0.000f 0.000c Finished all CC sets @ 71.5826569 0CUMULATIVE REACTION cross section = 104.19822 = 16.67 = 454.4 0CUMULATIVE outgoing cross sections in partition 1 : 0.00000 1.63092 6.47437 0.59963 0.96594 0CUMULATIVE outgoing cross sections in partition 2 : 8.33964 10.67787 2.44199 2.07852 1.11349 0.80722 0CUMULATIVE outgoing cross sections in partition 3 : 10.69842 3.17173 0CUMULATIVE outgoing cross sections in partition 4 : 21.97497 0Cumulative ABSORBTION by Imaginary Potentials = 33.22351 = 8.61 = 93.0 Fusion for specific 16-O M-states : 33.223509 0CUMULATIVE OUTGOING cross section = 70.97471 0Cumulative ABSORBTION in state 1 by Imaginary Potential 20 =*********** = 9.18 = 86.6 To convert to S-factors (MeV.mb = keV.b), multiply by 8.3989+127 CROSS SECTIONS FOR OUTGOING 16-O & PB-208 in state # 1 with spins & parities 0.0 + & 0.0 +; 0 80.00 deg.: X-S = 592.337366 mb/sr, + /R = 1.0006E+00 82.50 deg.: X-S = 535.012385 mb/sr, + /R = 1.0006E+00 85.00 deg.: X-S = 485.473897 mb/sr, + /R = 1.0008E+00 87.50 deg.: X-S = 442.185577 mb/sr, + /R = 1.0005E+00 90.00 deg.: X-S = 404.405810 mb/sr, + /R = 1.0004E+00 92.50 deg.: X-S = 371.721672 mb/sr, + /R = 1.0016E+00 95.00 deg.: X-S = 342.958229 mb/sr, + /R = 1.0028E+00 97.50 deg.: X-S = 317.120179 mb/sr, + /R = 1.0027E+00 100.00 deg.: X-S = 293.999322 mb/sr, + /R = 1.0018E+00 102.50 deg.: X-S = 273.741192 mb/sr, + /R = 1.0021E+00 105.00 deg.: X-S = 255.822606 mb/sr, + /R = 1.0029E+00 107.50 deg.: X-S = 239.153502 mb/sr, + /R = 1.0009E+00 110.00 deg.: X-S = 224.121248 mb/sr, + /R = 9.9856E-01 112.50 deg.: X-S = 211.397938 mb/sr, + /R = 9.9981E-01 115.00 deg.: X-S = 199.961191 mb/sr, + /R = 1.0011E+00 117.50 deg.: X-S = 189.201317 mb/sr, + /R = 1.0001E+00 120.00 deg.: X-S = 179.429776 mb/sr, + /R = 9.9873E-01 122.50 deg.: X-S = 169.680087 mb/sr, + /R = 9.9202E-01 125.00 deg.: X-S = 159.333064 mb/sr, + /R = 9.7601E-01 127.50 deg.: X-S = 148.916111 mb/sr, + /R = 9.5345E-01 130.00 deg.: X-S = 138.031619 mb/sr, + /R = 9.2154E-01 132.50 deg.: X-S = 126.824524 mb/sr, + /R = 8.8087E-01 135.00 deg.: X-S = 115.746596 mb/sr, + /R = 8.3445E-01 137.50 deg.: X-S = 104.775448 mb/sr, + /R = 7.8229E-01 140.00 deg.: X-S = 94.458716 mb/sr, + /R = 7.2881E-01 142.50 deg.: X-S = 84.672113 mb/sr, + /R = 6.7367E-01 145.00 deg.: X-S = 75.804182 mb/sr, + /R = 6.2059E-01 147.50 deg.: X-S = 67.742134 mb/sr, + /R = 5.6946E-01 150.00 deg.: X-S = 60.487633 mb/sr, + /R = 5.2104E-01 152.50 deg.: X-S = 54.342287 mb/sr, + /R = 4.7869E-01 155.00 deg.: X-S = 48.759391 mb/sr, + /R = 4.3835E-01 157.50 deg.: X-S = 44.361787 mb/sr, + /R = 4.0620E-01 160.00 deg.: X-S = 40.321018 mb/sr, + /R = 3.7529E-01 162.50 deg.: X-S = 37.228542 mb/sr, + /R = 3.5154E-01 165.00 deg.: X-S = 34.470443 mb/sr, + /R = 3.2957E-01 167.50 deg.: X-S = 32.357809 mb/sr, + /R = 3.1265E-01 170.00 deg.: X-S = 30.683963 mb/sr, + /R = 2.9903E-01 172.50 deg.: X-S = 29.379128 mb/sr, + /R = 2.8824E-01 175.00 deg.: X-S = 28.610370 mb/sr, + /R = 2.8203E-01 177.50 deg.: X-S = 27.967303 mb/sr, + /R = 2.7648E-01 179.99 deg.: X-S = 28.147556 mb/sr, + /R = 2.7853E-01 Integrated 1780.8656 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 16-O & PB-208 in state # 2 with spins & parities 3.0 - & 0.0 +; 0 80.00 deg.: X-S = 0.002492 mb/sr, + REAC 1.6309E+00 mb 82.50 deg.: X-S = 0.002020 mb/sr, 85.00 deg.: X-S = 0.001401 mb/sr, 87.50 deg.: X-S = 0.001071 mb/sr, 90.00 deg.: X-S = 0.001146 mb/sr, 92.50 deg.: X-S = 0.001441 mb/sr, 95.00 deg.: X-S = 0.001897 mb/sr, 97.50 deg.: X-S = 0.003088 mb/sr, 100.00 deg.: X-S = 0.005553 mb/sr, 102.50 deg.: X-S = 0.009022 mb/sr, 105.00 deg.: X-S = 0.013740 mb/sr, 107.50 deg.: X-S = 0.021393 mb/sr, 110.00 deg.: X-S = 0.032120 mb/sr, 112.50 deg.: X-S = 0.044646 mb/sr, 115.00 deg.: X-S = 0.061838 mb/sr, 117.50 deg.: X-S = 0.086168 mb/sr, 120.00 deg.: X-S = 0.114119 mb/sr, 122.50 deg.: X-S = 0.148667 mb/sr, 125.00 deg.: X-S = 0.193890 mb/sr, 127.50 deg.: X-S = 0.240853 mb/sr, 130.00 deg.: X-S = 0.293327 mb/sr, 132.50 deg.: X-S = 0.354118 mb/sr, 135.00 deg.: X-S = 0.408375 mb/sr, 137.50 deg.: X-S = 0.467151 mb/sr, 140.00 deg.: X-S = 0.525597 mb/sr, 142.50 deg.: X-S = 0.572504 mb/sr, 145.00 deg.: X-S = 0.623265 mb/sr, 147.50 deg.: X-S = 0.664799 mb/sr, 150.00 deg.: X-S = 0.703034 mb/sr, 152.50 deg.: X-S = 0.733359 mb/sr, 155.00 deg.: X-S = 0.759220 mb/sr, 157.50 deg.: X-S = 0.786662 mb/sr, 160.00 deg.: X-S = 0.803553 mb/sr, 162.50 deg.: X-S = 0.822597 mb/sr, 165.00 deg.: X-S = 0.830974 mb/sr, 167.50 deg.: X-S = 0.844477 mb/sr, 170.00 deg.: X-S = 0.849371 mb/sr, 172.50 deg.: X-S = 0.859452 mb/sr, 175.00 deg.: X-S = 0.861193 mb/sr, 177.50 deg.: X-S = 0.867730 mb/sr, 180.00 deg.: X-S = 0.862181 mb/sr, Integrated 1.6275 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 16-O & PB-208 in state # 3 with spins & parities 0.0 + & 3.0 -; 0 80.00 deg.: X-S = 1.512223 mb/sr, + REAC 6.4744E+00 mb 82.50 deg.: X-S = 1.324648 mb/sr, 85.00 deg.: X-S = 1.036730 mb/sr, 87.50 deg.: X-S = 0.865207 mb/sr, 90.00 deg.: X-S = 0.938105 mb/sr, 92.50 deg.: X-S = 1.118313 mb/sr, 95.00 deg.: X-S = 1.114441 mb/sr, 97.50 deg.: X-S = 0.881465 mb/sr, 100.00 deg.: X-S = 0.727365 mb/sr, 102.50 deg.: X-S = 0.809983 mb/sr, 105.00 deg.: X-S = 0.834717 mb/sr, 107.50 deg.: X-S = 0.631615 mb/sr, 110.00 deg.: X-S = 0.514536 mb/sr, 112.50 deg.: X-S = 0.572812 mb/sr, 115.00 deg.: X-S = 0.481237 mb/sr, 117.50 deg.: X-S = 0.319179 mb/sr, 120.00 deg.: X-S = 0.328024 mb/sr, 122.50 deg.: X-S = 0.278997 mb/sr, 125.00 deg.: X-S = 0.158520 mb/sr, 127.50 deg.: X-S = 0.156087 mb/sr, 130.00 deg.: X-S = 0.141012 mb/sr, 132.50 deg.: X-S = 0.106150 mb/sr, 135.00 deg.: X-S = 0.127592 mb/sr, 137.50 deg.: X-S = 0.188064 mb/sr, 140.00 deg.: X-S = 0.201539 mb/sr, 142.50 deg.: X-S = 0.284092 mb/sr, 145.00 deg.: X-S = 0.381742 mb/sr, 147.50 deg.: X-S = 0.399511 mb/sr, 150.00 deg.: X-S = 0.573724 mb/sr, 152.50 deg.: X-S = 0.559247 mb/sr, 155.00 deg.: X-S = 0.706166 mb/sr, 157.50 deg.: X-S = 0.751661 mb/sr, 160.00 deg.: X-S = 0.802091 mb/sr, 162.50 deg.: X-S = 0.918538 mb/sr, 165.00 deg.: X-S = 0.867201 mb/sr, 167.50 deg.: X-S = 1.041290 mb/sr, 170.00 deg.: X-S = 0.918579 mb/sr, 172.50 deg.: X-S = 1.134815 mb/sr, 175.00 deg.: X-S = 0.943660 mb/sr, 177.50 deg.: X-S = 1.256265 mb/sr, 180.00 deg.: X-S = 0.625226 mb/sr, Integrated 4.9008 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 16-O & PB-208 in state # 4 with spins & parities 0.0 + & 2.0 +; 0 80.00 deg.: X-S = 0.085179 mb/sr, + REAC 5.9963E-01 mb 82.50 deg.: X-S = 0.080616 mb/sr, 85.00 deg.: X-S = 0.070273 mb/sr, 87.50 deg.: X-S = 0.063358 mb/sr, 90.00 deg.: X-S = 0.067062 mb/sr, 92.50 deg.: X-S = 0.075669 mb/sr, 95.00 deg.: X-S = 0.075687 mb/sr, 97.50 deg.: X-S = 0.064347 mb/sr, 100.00 deg.: X-S = 0.054992 mb/sr, 102.50 deg.: X-S = 0.055057 mb/sr, 105.00 deg.: X-S = 0.052301 mb/sr, 107.50 deg.: X-S = 0.040253 mb/sr, 110.00 deg.: X-S = 0.031481 mb/sr, 112.50 deg.: X-S = 0.028736 mb/sr, 115.00 deg.: X-S = 0.021076 mb/sr, 117.50 deg.: X-S = 0.012456 mb/sr, 120.00 deg.: X-S = 0.010109 mb/sr, 122.50 deg.: X-S = 0.007178 mb/sr, 125.00 deg.: X-S = 0.004269 mb/sr, 127.50 deg.: X-S = 0.008017 mb/sr, 130.00 deg.: X-S = 0.015837 mb/sr, 132.50 deg.: X-S = 0.022584 mb/sr, 135.00 deg.: X-S = 0.037198 mb/sr, 137.50 deg.: X-S = 0.057433 mb/sr, 140.00 deg.: X-S = 0.066937 mb/sr, 142.50 deg.: X-S = 0.095795 mb/sr, 145.00 deg.: X-S = 0.116552 mb/sr, 147.50 deg.: X-S = 0.123599 mb/sr, 150.00 deg.: X-S = 0.160914 mb/sr, 152.50 deg.: X-S = 0.168336 mb/sr, 155.00 deg.: X-S = 0.192387 mb/sr, 157.50 deg.: X-S = 0.198364 mb/sr, 160.00 deg.: X-S = 0.211068 mb/sr, 162.50 deg.: X-S = 0.236202 mb/sr, 165.00 deg.: X-S = 0.234201 mb/sr, 167.50 deg.: X-S = 0.263125 mb/sr, 170.00 deg.: X-S = 0.244286 mb/sr, 172.50 deg.: X-S = 0.275011 mb/sr, 175.00 deg.: X-S = 0.246420 mb/sr, 177.50 deg.: X-S = 0.286612 mb/sr, 180.00 deg.: X-S = 0.202533 mb/sr, Integrated 0.5219 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 16-O & PB-208 in state # 5 with spins & parities 0.0 + & 5.0 -; 0 80.00 deg.: X-S = 0.004633 mb/sr, + REAC 9.6594E-01 mb 82.50 deg.: X-S = 0.004206 mb/sr, 85.00 deg.: X-S = 0.003250 mb/sr, 87.50 deg.: X-S = 0.002479 mb/sr, 90.00 deg.: X-S = 0.002218 mb/sr, 92.50 deg.: X-S = 0.002273 mb/sr, 95.00 deg.: X-S = 0.002014 mb/sr, 97.50 deg.: X-S = 0.001435 mb/sr, 100.00 deg.: X-S = 0.001309 mb/sr, 102.50 deg.: X-S = 0.001905 mb/sr, 105.00 deg.: X-S = 0.002862 mb/sr, 107.50 deg.: X-S = 0.004686 mb/sr, 110.00 deg.: X-S = 0.008221 mb/sr, 112.50 deg.: X-S = 0.012890 mb/sr, 115.00 deg.: X-S = 0.019246 mb/sr, 117.50 deg.: X-S = 0.029638 mb/sr, 120.00 deg.: X-S = 0.043233 mb/sr, 122.50 deg.: X-S = 0.059744 mb/sr, 125.00 deg.: X-S = 0.083230 mb/sr, 127.50 deg.: X-S = 0.111254 mb/sr, 130.00 deg.: X-S = 0.141849 mb/sr, 132.50 deg.: X-S = 0.180149 mb/sr, 135.00 deg.: X-S = 0.219130 mb/sr, 137.50 deg.: X-S = 0.258953 mb/sr, 140.00 deg.: X-S = 0.303315 mb/sr, 142.50 deg.: X-S = 0.341505 mb/sr, 145.00 deg.: X-S = 0.381755 mb/sr, 147.50 deg.: X-S = 0.417832 mb/sr, 150.00 deg.: X-S = 0.448458 mb/sr, 152.50 deg.: X-S = 0.480488 mb/sr, 155.00 deg.: X-S = 0.502170 mb/sr, 157.50 deg.: X-S = 0.527249 mb/sr, 160.00 deg.: X-S = 0.543193 mb/sr, 162.50 deg.: X-S = 0.560013 mb/sr, 165.00 deg.: X-S = 0.572472 mb/sr, 167.50 deg.: X-S = 0.581726 mb/sr, 170.00 deg.: X-S = 0.591965 mb/sr, 172.50 deg.: X-S = 0.594804 mb/sr, 175.00 deg.: X-S = 0.603636 mb/sr, 177.50 deg.: X-S = 0.599718 mb/sr, 180.00 deg.: X-S = 0.617424 mb/sr, Integrated 0.9611 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 17-O & PB-207 in state # 1 with spins & parities 2.5 + & 0.5 -; 0 80.00 deg.: X-S = 0.234098 mb/sr, + REAC 8.3396E+00 mb 82.50 deg.: X-S = 0.280176 mb/sr, 85.00 deg.: X-S = 0.310118 mb/sr, 87.50 deg.: X-S = 0.341961 mb/sr, 90.00 deg.: X-S = 0.399854 mb/sr, 92.50 deg.: X-S = 0.487224 mb/sr, 95.00 deg.: X-S = 0.574742 mb/sr, 97.50 deg.: X-S = 0.629090 mb/sr, 100.00 deg.: X-S = 0.672138 mb/sr, 102.50 deg.: X-S = 0.755804 mb/sr, 105.00 deg.: X-S = 0.860499 mb/sr, 107.50 deg.: X-S = 0.923228 mb/sr, 110.00 deg.: X-S = 0.971805 mb/sr, 112.50 deg.: X-S = 1.069231 mb/sr, 115.00 deg.: X-S = 1.159798 mb/sr, 117.50 deg.: X-S = 1.207527 mb/sr, 120.00 deg.: X-S = 1.302864 mb/sr, 122.50 deg.: X-S = 1.416469 mb/sr, 125.00 deg.: X-S = 1.473781 mb/sr, 127.50 deg.: X-S = 1.573730 mb/sr, 130.00 deg.: X-S = 1.673260 mb/sr, 132.50 deg.: X-S = 1.707157 mb/sr, 135.00 deg.: X-S = 1.791205 mb/sr, 137.50 deg.: X-S = 1.820984 mb/sr, 140.00 deg.: X-S = 1.823062 mb/sr, 142.50 deg.: X-S = 1.860807 mb/sr, 145.00 deg.: X-S = 1.812141 mb/sr, 147.50 deg.: X-S = 1.816874 mb/sr, 150.00 deg.: X-S = 1.770483 mb/sr, 152.50 deg.: X-S = 1.724518 mb/sr, 155.00 deg.: X-S = 1.703338 mb/sr, 157.50 deg.: X-S = 1.628558 mb/sr, 160.00 deg.: X-S = 1.626764 mb/sr, 162.50 deg.: X-S = 1.550131 mb/sr, 165.00 deg.: X-S = 1.553995 mb/sr, 167.50 deg.: X-S = 1.491073 mb/sr, 170.00 deg.: X-S = 1.493779 mb/sr, 172.50 deg.: X-S = 1.449756 mb/sr, 175.00 deg.: X-S = 1.453117 mb/sr, 177.50 deg.: X-S = 1.428432 mb/sr, 180.00 deg.: X-S = 1.449143 mb/sr, Integrated 8.2034 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 17-O & PB-207 in state # 2 with spins & parities 2.5 + & 2.5 -; 0 80.00 deg.: X-S = 0.193770 mb/sr, + REAC 1.0678E+01 mb 82.50 deg.: X-S = 0.246056 mb/sr, 85.00 deg.: X-S = 0.291156 mb/sr, 87.50 deg.: X-S = 0.332287 mb/sr, 90.00 deg.: X-S = 0.392143 mb/sr, 92.50 deg.: X-S = 0.483947 mb/sr, 95.00 deg.: X-S = 0.591803 mb/sr, 97.50 deg.: X-S = 0.682999 mb/sr, 100.00 deg.: X-S = 0.754188 mb/sr, 102.50 deg.: X-S = 0.848356 mb/sr, 105.00 deg.: X-S = 0.981363 mb/sr, 107.50 deg.: X-S = 1.100657 mb/sr, 110.00 deg.: X-S = 1.187657 mb/sr, 112.50 deg.: X-S = 1.303459 mb/sr, 115.00 deg.: X-S = 1.448988 mb/sr, 117.50 deg.: X-S = 1.557492 mb/sr, 120.00 deg.: X-S = 1.669571 mb/sr, 122.50 deg.: X-S = 1.834130 mb/sr, 125.00 deg.: X-S = 1.967292 mb/sr, 127.50 deg.: X-S = 2.083325 mb/sr, 130.00 deg.: X-S = 2.242526 mb/sr, 132.50 deg.: X-S = 2.346708 mb/sr, 135.00 deg.: X-S = 2.431662 mb/sr, 137.50 deg.: X-S = 2.531641 mb/sr, 140.00 deg.: X-S = 2.548724 mb/sr, 142.50 deg.: X-S = 2.578847 mb/sr, 145.00 deg.: X-S = 2.577283 mb/sr, 147.50 deg.: X-S = 2.529450 mb/sr, 150.00 deg.: X-S = 2.513143 mb/sr, 152.50 deg.: X-S = 2.432459 mb/sr, 155.00 deg.: X-S = 2.390510 mb/sr, 157.50 deg.: X-S = 2.319859 mb/sr, 160.00 deg.: X-S = 2.257436 mb/sr, 162.50 deg.: X-S = 2.211875 mb/sr, 165.00 deg.: X-S = 2.141890 mb/sr, 167.50 deg.: X-S = 2.120253 mb/sr, 170.00 deg.: X-S = 2.054562 mb/sr, 172.50 deg.: X-S = 2.055235 mb/sr, 175.00 deg.: X-S = 1.997851 mb/sr, 177.50 deg.: X-S = 2.027913 mb/sr, 180.00 deg.: X-S = 1.922279 mb/sr, Integrated 10.5767 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 17-O & PB-207 in state # 3 with spins & parities 2.5 + & 1.5 -; 0 80.00 deg.: X-S = 0.076870 mb/sr, + REAC 2.4420E+00 mb 82.50 deg.: X-S = 0.091892 mb/sr, 85.00 deg.: X-S = 0.101623 mb/sr, 87.50 deg.: X-S = 0.112122 mb/sr, 90.00 deg.: X-S = 0.131046 mb/sr, 92.50 deg.: X-S = 0.159145 mb/sr, 95.00 deg.: X-S = 0.186831 mb/sr, 97.50 deg.: X-S = 0.203767 mb/sr, 100.00 deg.: X-S = 0.216992 mb/sr, 102.50 deg.: X-S = 0.242582 mb/sr, 105.00 deg.: X-S = 0.274306 mb/sr, 107.50 deg.: X-S = 0.292585 mb/sr, 110.00 deg.: X-S = 0.306213 mb/sr, 112.50 deg.: X-S = 0.334473 mb/sr, 115.00 deg.: X-S = 0.359614 mb/sr, 117.50 deg.: X-S = 0.370982 mb/sr, 120.00 deg.: X-S = 0.396238 mb/sr, 122.50 deg.: X-S = 0.425429 mb/sr, 125.00 deg.: X-S = 0.436629 mb/sr, 127.50 deg.: X-S = 0.459361 mb/sr, 130.00 deg.: X-S = 0.480545 mb/sr, 132.50 deg.: X-S = 0.483325 mb/sr, 135.00 deg.: X-S = 0.500100 mb/sr, 137.50 deg.: X-S = 0.502124 mb/sr, 140.00 deg.: X-S = 0.498369 mb/sr, 142.50 deg.: X-S = 0.503518 mb/sr, 145.00 deg.: X-S = 0.487683 mb/sr, 147.50 deg.: X-S = 0.486022 mb/sr, 150.00 deg.: X-S = 0.470924 mb/sr, 152.50 deg.: X-S = 0.458637 mb/sr, 155.00 deg.: X-S = 0.450011 mb/sr, 157.50 deg.: X-S = 0.431592 mb/sr, 160.00 deg.: X-S = 0.428590 mb/sr, 162.50 deg.: X-S = 0.409582 mb/sr, 165.00 deg.: X-S = 0.409583 mb/sr, 167.50 deg.: X-S = 0.393254 mb/sr, 170.00 deg.: X-S = 0.394463 mb/sr, 172.50 deg.: X-S = 0.381765 mb/sr, 175.00 deg.: X-S = 0.384282 mb/sr, 177.50 deg.: X-S = 0.375339 mb/sr, 180.00 deg.: X-S = 0.386663 mb/sr, Integrated 2.3976 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 17-O & PB-207 in state # 4 with spins & parities 0.5 + & 0.5 -; 0 80.00 deg.: X-S = 0.050885 mb/sr, + REAC 2.0785E+00 mb 82.50 deg.: X-S = 0.059111 mb/sr, 85.00 deg.: X-S = 0.064848 mb/sr, 87.50 deg.: X-S = 0.073039 mb/sr, 90.00 deg.: X-S = 0.087453 mb/sr, 92.50 deg.: X-S = 0.107400 mb/sr, 95.00 deg.: X-S = 0.124968 mb/sr, 97.50 deg.: X-S = 0.136247 mb/sr, 100.00 deg.: X-S = 0.150073 mb/sr, 102.50 deg.: X-S = 0.173236 mb/sr, 105.00 deg.: X-S = 0.196298 mb/sr, 107.50 deg.: X-S = 0.210314 mb/sr, 110.00 deg.: X-S = 0.227780 mb/sr, 112.50 deg.: X-S = 0.254768 mb/sr, 115.00 deg.: X-S = 0.274262 mb/sr, 117.50 deg.: X-S = 0.291540 mb/sr, 120.00 deg.: X-S = 0.322416 mb/sr, 122.50 deg.: X-S = 0.346783 mb/sr, 125.00 deg.: X-S = 0.365336 mb/sr, 127.50 deg.: X-S = 0.396118 mb/sr, 130.00 deg.: X-S = 0.414513 mb/sr, 132.50 deg.: X-S = 0.429966 mb/sr, 135.00 deg.: X-S = 0.450905 mb/sr, 137.50 deg.: X-S = 0.455204 mb/sr, 140.00 deg.: X-S = 0.468728 mb/sr, 142.50 deg.: X-S = 0.472775 mb/sr, 145.00 deg.: X-S = 0.473838 mb/sr, 147.50 deg.: X-S = 0.479300 mb/sr, 150.00 deg.: X-S = 0.470484 mb/sr, 152.50 deg.: X-S = 0.477166 mb/sr, 155.00 deg.: X-S = 0.465329 mb/sr, 157.50 deg.: X-S = 0.470633 mb/sr, 160.00 deg.: X-S = 0.461454 mb/sr, 162.50 deg.: X-S = 0.462253 mb/sr, 165.00 deg.: X-S = 0.458862 mb/sr, 167.50 deg.: X-S = 0.453714 mb/sr, 170.00 deg.: X-S = 0.456171 mb/sr, 172.50 deg.: X-S = 0.445199 mb/sr, 175.00 deg.: X-S = 0.453688 mb/sr, 177.50 deg.: X-S = 0.437231 mb/sr, 180.00 deg.: X-S = 0.472615 mb/sr, Integrated 2.0482 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 17-O & PB-207 in state # 5 with spins & parities 0.5 + & 2.5 -; 0 80.00 deg.: X-S = 0.021641 mb/sr, + REAC 1.1135E+00 mb 82.50 deg.: X-S = 0.026785 mb/sr, 85.00 deg.: X-S = 0.030800 mb/sr, 87.50 deg.: X-S = 0.035199 mb/sr, 90.00 deg.: X-S = 0.042268 mb/sr, 92.50 deg.: X-S = 0.052168 mb/sr, 95.00 deg.: X-S = 0.062470 mb/sr, 97.50 deg.: X-S = 0.070419 mb/sr, 100.00 deg.: X-S = 0.077761 mb/sr, 102.50 deg.: X-S = 0.089069 mb/sr, 105.00 deg.: X-S = 0.102587 mb/sr, 107.50 deg.: X-S = 0.112813 mb/sr, 110.00 deg.: X-S = 0.122132 mb/sr, 112.50 deg.: X-S = 0.135939 mb/sr, 115.00 deg.: X-S = 0.149566 mb/sr, 117.50 deg.: X-S = 0.159845 mb/sr, 120.00 deg.: X-S = 0.174281 mb/sr, 122.50 deg.: X-S = 0.190384 mb/sr, 125.00 deg.: X-S = 0.201585 mb/sr, 127.50 deg.: X-S = 0.215695 mb/sr, 130.00 deg.: X-S = 0.229392 mb/sr, 132.50 deg.: X-S = 0.236931 mb/sr, 135.00 deg.: X-S = 0.247683 mb/sr, 137.50 deg.: X-S = 0.253891 mb/sr, 140.00 deg.: X-S = 0.256670 mb/sr, 142.50 deg.: X-S = 0.262377 mb/sr, 145.00 deg.: X-S = 0.260336 mb/sr, 147.50 deg.: X-S = 0.261646 mb/sr, 150.00 deg.: X-S = 0.259803 mb/sr, 152.50 deg.: X-S = 0.255755 mb/sr, 155.00 deg.: X-S = 0.255911 mb/sr, 157.50 deg.: X-S = 0.249578 mb/sr, 160.00 deg.: X-S = 0.250472 mb/sr, 162.50 deg.: X-S = 0.244982 mb/sr, 165.00 deg.: X-S = 0.244923 mb/sr, 167.50 deg.: X-S = 0.241557 mb/sr, 170.00 deg.: X-S = 0.239842 mb/sr, 172.50 deg.: X-S = 0.238711 mb/sr, 175.00 deg.: X-S = 0.235699 mb/sr, 177.50 deg.: X-S = 0.237454 mb/sr, 180.00 deg.: X-S = 0.230015 mb/sr, Integrated 1.1015 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 17-O & PB-207 in state # 6 with spins & parities 0.5 + & 1.5 -; 0 80.00 deg.: X-S = 0.018463 mb/sr, + REAC 8.0722E-01 mb 82.50 deg.: X-S = 0.022127 mb/sr, 85.00 deg.: X-S = 0.024854 mb/sr, 87.50 deg.: X-S = 0.028378 mb/sr, 90.00 deg.: X-S = 0.034133 mb/sr, 92.50 deg.: X-S = 0.042057 mb/sr, 95.00 deg.: X-S = 0.049334 mb/sr, 97.50 deg.: X-S = 0.054217 mb/sr, 100.00 deg.: X-S = 0.059747 mb/sr, 102.50 deg.: X-S = 0.068733 mb/sr, 105.00 deg.: X-S = 0.078212 mb/sr, 107.50 deg.: X-S = 0.084438 mb/sr, 110.00 deg.: X-S = 0.091310 mb/sr, 112.50 deg.: X-S = 0.101893 mb/sr, 115.00 deg.: X-S = 0.110100 mb/sr, 117.50 deg.: X-S = 0.116537 mb/sr, 120.00 deg.: X-S = 0.127775 mb/sr, 122.50 deg.: X-S = 0.137312 mb/sr, 125.00 deg.: X-S = 0.143763 mb/sr, 127.50 deg.: X-S = 0.154651 mb/sr, 130.00 deg.: X-S = 0.161693 mb/sr, 132.50 deg.: X-S = 0.166493 mb/sr, 135.00 deg.: X-S = 0.173976 mb/sr, 137.50 deg.: X-S = 0.175313 mb/sr, 140.00 deg.: X-S = 0.179288 mb/sr, 142.50 deg.: X-S = 0.180971 mb/sr, 145.00 deg.: X-S = 0.180160 mb/sr, 147.50 deg.: X-S = 0.182258 mb/sr, 150.00 deg.: X-S = 0.178423 mb/sr, 152.50 deg.: X-S = 0.180610 mb/sr, 155.00 deg.: X-S = 0.176856 mb/sr, 157.50 deg.: X-S = 0.178005 mb/sr, 160.00 deg.: X-S = 0.176245 mb/sr, 162.50 deg.: X-S = 0.175307 mb/sr, 165.00 deg.: X-S = 0.176170 mb/sr, 167.50 deg.: X-S = 0.172873 mb/sr, 170.00 deg.: X-S = 0.175838 mb/sr, 172.50 deg.: X-S = 0.170328 mb/sr, 175.00 deg.: X-S = 0.175294 mb/sr, 177.50 deg.: X-S = 0.167529 mb/sr, 180.00 deg.: X-S = 0.184134 mb/sr, Integrated 0.7967 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 15-N & BI-209 in state # 1 with spins & parities 0.5 - & 3.5 -; 0 80.00 deg.: X-S = 0.015684 mb/sr, + REAC 1.0698E+01 mb 82.50 deg.: X-S = 0.021663 mb/sr, 85.00 deg.: X-S = 0.030752 mb/sr, 87.50 deg.: X-S = 0.044738 mb/sr, 90.00 deg.: X-S = 0.062163 mb/sr, 92.50 deg.: X-S = 0.082994 mb/sr, 95.00 deg.: X-S = 0.109431 mb/sr, 97.50 deg.: X-S = 0.144425 mb/sr, 100.00 deg.: X-S = 0.190377 mb/sr, 102.50 deg.: X-S = 0.244110 mb/sr, 105.00 deg.: X-S = 0.301395 mb/sr, 107.50 deg.: X-S = 0.367086 mb/sr, 110.00 deg.: X-S = 0.448296 mb/sr, 112.50 deg.: X-S = 0.552358 mb/sr, 115.00 deg.: X-S = 0.697211 mb/sr, 117.50 deg.: X-S = 0.901231 mb/sr, 120.00 deg.: X-S = 1.165697 mb/sr, 122.50 deg.: X-S = 1.485961 mb/sr, 125.00 deg.: X-S = 1.856012 mb/sr, 127.50 deg.: X-S = 2.247716 mb/sr, 130.00 deg.: X-S = 2.632589 mb/sr, 132.50 deg.: X-S = 2.992811 mb/sr, 135.00 deg.: X-S = 3.300890 mb/sr, 137.50 deg.: X-S = 3.549231 mb/sr, 140.00 deg.: X-S = 3.729541 mb/sr, 142.50 deg.: X-S = 3.835191 mb/sr, 145.00 deg.: X-S = 3.883665 mb/sr, 147.50 deg.: X-S = 3.874312 mb/sr, 150.00 deg.: X-S = 3.826132 mb/sr, 152.50 deg.: X-S = 3.745068 mb/sr, 155.00 deg.: X-S = 3.640258 mb/sr, 157.50 deg.: X-S = 3.527315 mb/sr, 160.00 deg.: X-S = 3.406879 mb/sr, 162.50 deg.: X-S = 3.297955 mb/sr, 165.00 deg.: X-S = 3.193351 mb/sr, 167.50 deg.: X-S = 3.109242 mb/sr, 170.00 deg.: X-S = 3.033979 mb/sr, 172.50 deg.: X-S = 2.981144 mb/sr, 175.00 deg.: X-S = 2.937831 mb/sr, 177.50 deg.: X-S = 2.917701 mb/sr, 180.00 deg.: X-S = 2.901326 mb/sr, Integrated 10.6889 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 15-N & BI-209 in state # 2 with spins & parities 0.5 - & 1.5 -; 0 80.00 deg.: X-S = 0.003752 mb/sr, + REAC 3.1717E+00 mb 82.50 deg.: X-S = 0.005470 mb/sr, 85.00 deg.: X-S = 0.008183 mb/sr, 87.50 deg.: X-S = 0.012033 mb/sr, 90.00 deg.: X-S = 0.017108 mb/sr, 92.50 deg.: X-S = 0.023676 mb/sr, 95.00 deg.: X-S = 0.031966 mb/sr, 97.50 deg.: X-S = 0.042593 mb/sr, 100.00 deg.: X-S = 0.056368 mb/sr, 102.50 deg.: X-S = 0.073180 mb/sr, 105.00 deg.: X-S = 0.092802 mb/sr, 107.50 deg.: X-S = 0.115952 mb/sr, 110.00 deg.: X-S = 0.143381 mb/sr, 112.50 deg.: X-S = 0.176154 mb/sr, 115.00 deg.: X-S = 0.216816 mb/sr, 117.50 deg.: X-S = 0.267112 mb/sr, 120.00 deg.: X-S = 0.326633 mb/sr, 122.50 deg.: X-S = 0.395974 mb/sr, 125.00 deg.: X-S = 0.474700 mb/sr, 127.50 deg.: X-S = 0.559571 mb/sr, 130.00 deg.: X-S = 0.649394 mb/sr, 132.50 deg.: X-S = 0.740498 mb/sr, 135.00 deg.: X-S = 0.828392 mb/sr, 137.50 deg.: X-S = 0.912451 mb/sr, 140.00 deg.: X-S = 0.988105 mb/sr, 142.50 deg.: X-S = 1.055092 mb/sr, 145.00 deg.: X-S = 1.112222 mb/sr, 147.50 deg.: X-S = 1.157035 mb/sr, 150.00 deg.: X-S = 1.193034 mb/sr, 152.50 deg.: X-S = 1.218428 mb/sr, 155.00 deg.: X-S = 1.237902 mb/sr, 157.50 deg.: X-S = 1.251022 mb/sr, 160.00 deg.: X-S = 1.259581 mb/sr, 162.50 deg.: X-S = 1.264948 mb/sr, 165.00 deg.: X-S = 1.266491 mb/sr, 167.50 deg.: X-S = 1.267539 mb/sr, 170.00 deg.: X-S = 1.265919 mb/sr, 172.50 deg.: X-S = 1.265818 mb/sr, 175.00 deg.: X-S = 1.263659 mb/sr, 177.50 deg.: X-S = 1.264381 mb/sr, 180.00 deg.: X-S = 1.260805 mb/sr, Integrated 3.1690 mb, over [ 80.000, 180.000] at 80.0000 MeV CROSS SECTIONS FOR OUTGOING 12-C & PO-212 in state # 1 with spins & parities 0.0 + & 0.0 +; 0 80.00 deg.: X-S = 0.001499 mb/sr, + REAC 2.1975E+01 mb 82.50 deg.: X-S = 0.003187 mb/sr, 85.00 deg.: X-S = 0.006208 mb/sr, 87.50 deg.: X-S = 0.012184 mb/sr, 90.00 deg.: X-S = 0.022352 mb/sr, 92.50 deg.: X-S = 0.039898 mb/sr, 95.00 deg.: X-S = 0.068444 mb/sr, 97.50 deg.: X-S = 0.110207 mb/sr, 100.00 deg.: X-S = 0.172005 mb/sr, 102.50 deg.: X-S = 0.259314 mb/sr, 105.00 deg.: X-S = 0.374498 mb/sr, 107.50 deg.: X-S = 0.529324 mb/sr, 110.00 deg.: X-S = 0.738802 mb/sr, 112.50 deg.: X-S = 1.011987 mb/sr, 115.00 deg.: X-S = 1.359380 mb/sr, 117.50 deg.: X-S = 1.788707 mb/sr, 120.00 deg.: X-S = 2.294895 mb/sr, 122.50 deg.: X-S = 2.867551 mb/sr, 125.00 deg.: X-S = 3.496339 mb/sr, 127.50 deg.: X-S = 4.162689 mb/sr, 130.00 deg.: X-S = 4.839442 mb/sr, 132.50 deg.: X-S = 5.501787 mb/sr, 135.00 deg.: X-S = 6.130474 mb/sr, 137.50 deg.: X-S = 6.707207 mb/sr, 140.00 deg.: X-S = 7.215394 mb/sr, 142.50 deg.: X-S = 7.645714 mb/sr, 145.00 deg.: X-S = 7.996284 mb/sr, 147.50 deg.: X-S = 8.267926 mb/sr, 150.00 deg.: X-S = 8.463094 mb/sr, 152.50 deg.: X-S = 8.588804 mb/sr, 155.00 deg.: X-S = 8.659008 mb/sr, 157.50 deg.: X-S = 8.690732 mb/sr, 160.00 deg.: X-S = 8.698339 mb/sr, 162.50 deg.: X-S = 8.689452 mb/sr, 165.00 deg.: X-S = 8.666735 mb/sr, 167.50 deg.: X-S = 8.632035 mb/sr, 170.00 deg.: X-S = 8.589226 mb/sr, 172.50 deg.: X-S = 8.544898 mb/sr, 175.00 deg.: X-S = 8.506275 mb/sr, 177.50 deg.: X-S = 8.480246 mb/sr, 180.00 deg.: X-S = 8.470828 mb/sr, Integrated 21.9662 mb, over [ 80.000, 180.000] at 80.0000 MeV Finished all xsecs @ 71.6082153 Mean components of Elastic Optical Potential generated by channel couplings of type 1 0.500 -0.3597 0.1731 1.000 -6.5652 3.1615 1.500 -7.6314 6.0548 2.000 -7.8931 8.4736 2.500 -8.8865 9.1287 3.000 -9.4087 9.8086 3.500 -8.9719 11.3519 4.000 -7.5507 12.3606 4.500 -5.8302 11.6282 5.000 -4.5977 9.2484 5.500 -4.0484 6.4422 6.000 -2.6668 4.1418 6.500 -1.2384 3.5928 7.000 -1.0034 2.6831 7.500 -1.8752 2.9659 8.000 -3.1054 -8.4358 8.500 -7.3250 4.0184 9.000 -8.3509 -11.9871 9.500 2.1186 2.6156 10.000 -7.6213 6.6118 10.500 -8.7427 0.3606 11.000 -5.4886 1.0469 11.500 -2.9991 0.6431 12.000 -1.4363 0.1667 12.500 -0.6602 -0.1374 13.000 -0.2544 -0.1568 13.500 -0.0948 -0.0838 14.000 -0.0428 -0.0416 14.500 -0.0153 -0.0055 15.000 -0.0171 0.0007 15.500 -0.0073 -0.0030 16.000 -0.0062 0.0023 16.500 -0.0036 -0.0010 17.000 -0.0032 0.0008 17.500 -0.0019 -0.0006 18.000 -0.0021 -0.0000 18.500 -0.0012 -0.0004 19.000 -0.0015 -0.0005 19.500 -0.0010 -0.0002 20.000 -0.0008 -0.0006 20.500 -0.0010 -0.0005 21.000 -0.0006 -0.0003 21.500 -0.0005 -0.0005 22.000 -0.0007 -0.0005 22.500 -0.0006 -0.0003 23.000 -0.0003 -0.0003 23.500 -0.0004 -0.0004 24.000 -0.0005 -0.0004 24.500 -0.0005 -0.0002 25.000 -0.0003 -0.0001 25.500 -0.0003 -0.0002 26.000 -0.0003 -0.0002 26.500 -0.0004 -0.0001 27.000 -0.0003 0.0000 27.500 -0.0002 0.0000 28.000 -0.0002 0.0000 28.500 -0.0002 -0.0000 29.000 -0.0002 0.0000 29.500 -0.0002 0.0001 30.000 -0.0002 0.0002 The following files have been created: 3:local copy of User input. 6:standard output. 7:elastic S-matrix elements. 12:transfer kernels. 13:total cross sections/state. 15:local equivalent potentials. 35:Astrophysics S-factors / Ecm. 38:cross sections for each J/pi. 39:cross sections for each Ecm. 40:all cross sectns. for each Elab. 45:scat phase shift as E functions. 46:bs wave functions & ANC ratios. 56:Fusion for each Jtotal. 75:S-factors for lab energies. 90:average polarisation potential. 91:polarisation potl for rereading. PARAMETERS : MAXQRN MFNL MLOC LMAX1 MCLIST ALLOWED : 37 6241 36 120 17 REQUIRED: 6 61 36 80 3 ACCURACY ANALYSIS at 80.000 MeV : Elastic h*k = 0.182 so OK compared with 0.200 Real(S-el) > 0.01 first at J = 1.0 Real(S-el) > 0.10 first at J = 1.0 Real(S-el) > 0.50 first at J = 10.0 Real(S-el) > 0.90 first at J = 20.0 Real(S-el) > 0.99 first at J = 35.0 R-turn = 18.42 fm at J = 74.0 Forward-angle excitation cut off below 71.054 deg by max JT = 74.0 and below 24.285 deg by max R. 1: Recommended RNL: non-local width > 0.58 cf: 6.00 fm: OK Recommended CENTRE: centration ~ 0.01 cf: 0.00 fm 2: Recommended RNL: non-local width > 0.70 cf: 6.00 fm: OK Recommended CENTRE: centration ~ -0.05 cf: 0.00 fm 3: Recommended RNL: non-local width > 4.55 cf: 6.00 fm: OK Recommended CENTRE: centration ~ -0.10 cf: 0.00 fm Total CPU 0 time = 71.62 seconds