QRPA calculations of stellar weak decay rates

QRPA calculations of stellar weak decay rates P. Sarriguren Instituto de Estructura de la Materia CSIC, Madrid, Spain E. Moya de Guerra, R. Alvarez-Rodriguez, O. Moreno Universidad Complutense Madrid International School of Nuclear Physics. 36 th Course. Nuclei in the Laboratory and in the Cosmos. Erice-Sicily. September 16-24, 2014

Problem : Weak-decay rates determine late stages of stellar evolution. Experimental extrapolations or theoretical predictions: Reproduce exp information on T 1/2 and BGT under terrestrial conditions. Theoretical approach : Weak-decay rates Deformed HF+BCS+QRPA formalism with Skyrme forces and residual interactions in both ph and pp channels. Results : Weak-decay rates at various (,T) in stellar scenarios pf-shell nuclei. Main constituents of stellar core in presupernova formations: Sc, Ti, V, Mn, Fe, Co, Ni, Zn isotopes. BGT measured in laboratory (Charge exchange reactions) and compared with benchmark Shell Model calculations. Neutron-deficient waiting-point isotopes (Ni-Sn) at (,T) typical of rpprocess. Neutron rich Zr-Mo isotopes: r process.

Weak decay rates ln 2 ln 2 T ( ) if 1 1/2 Pi T Bif, D if T Initial states thermally populated 2Ji 1 PT i( ) e, G2J1 e G Nuclear structure Ei /( kt ) Ei /( kt ) i i 2 2 g A k k Bif ( GT ) f t i gv k eff P ( 0) 1 ig.. s T Phase space factors : EC if if if +, EC : - : if if are different from laboratory (P i, cec)

Q if Q if 1( Q ) F( Z 1, ) 1 S 1 S ( Q ) d 2 2 if 1 if p if cec 2 2 if if e if Phase space factors 1( Q ) F( Z 1, ) 1 S 1 S ( Q ) d 2 2 if 1 if e if 1( Q ) F( Z, ) S 1 S ( Q ) d oec 2 2 2 2 qk gk BK ql g 1 L B 1 L 1 2 q Neutrino energy g Radial components of the e-wf at r=0 B Exchange and overlap corrections Distribution functions S p =S S e : Fermi-Dirac distribution 1 Se exp e / kt 1 1 Q M M E E if 2 p d i f mc e

Hartree-Fock method A H T k W k, l k1 kl1 How to extract a single-particle potential U(k) out of the sum of two-body interactions W(k,l) A H A A A Tk UkW k, luk H0 V k 1 k l 1 k1 res Hartree-Fock: Selfconsistent method to derive the single-particle potential Variational principle: Search for the best Slater det. minimizing the energy Assume that the resulting residual interaction is small

Skyrme effective interactions Two-body interaction: zero-range limit of a finite range force leading term: delta-function with strength t 0 and spin exchange x 0 leading finite range corrections t 1, x 1, t 2, x 2 (finite range = momentum dependence) short-range spin-orbit interaction with strength W 0 Short-range density-dependent two-body force t 3, x 3, V ij 1 2 2 t0 1 x0p ri rj t1 1 x1p ri rj k k' 2 t 2 1 x2p k' ri rj k iw0 i j k ' ri rj k 1 r i r j t3 1x3P ri rj 6 2 Parameters (10) fitted using nuclear matter properties and ground state properties of a selected set of nuclei (binding energies, charge radii, ) Sk3, SG2, SLy4

2m r,, q m r U r W r 2m U q * q 2 2 r Skyrme Hartree-Fock Schroedinger equation 2 U q r W r i i eii Algebraic combinations of the densities 1 1 t1 x1 t2 x2 r t1 x1 t2 x2 r 2m 8 8 2 2 1 2 1 2 q 1 1 1 1 2 2 r t 0 2x012x0 q t3 2x32 2x3 12 q p n 2 24 1 1 1 2 12 1 22 2 21 2 2 11 2 1 3 12 1 22 2 8 t x t x 8 t x t x q 16 t x t x 1 2 1 1 3t112x1t212x2 q t1t2jq t1x1t2x2j 16 qp, Vcoulr 8 8 Wq 2 1 r W0 q,,j 2 2 * r rst,,, r rst,,, J st r rs, ', ti rst,, st i st i i i i i i, s'

Axially symmetric deformed nuclei,,, i 1/2, i R q q r z e r ze 1/2 i i i i q i i Expansion into eigenfunctions of deformed harmonic oscillator 1 1 V(, r z) M r M z 2 2 2 2 2 2 z i, ( ) ( ) e R 2 ( ) n r r n z z /2 /2 n () r N n 2 e L n () r r r 1/2 /2 n ( z) Nn z e Hn ( ) z z z 2 Optimal basis to minimize truncation effects N= 12 major shells 1/2 2 2 o M z z q z z 2 1/3 1/3 i R,, q C R,, n, n,, i qi r z

Pairing correlations in BCS approximation BCS ground state u va a BCS i i i i i0 ' H a a a a G a a a a k k k k k k k k' k k0 kk' 0 0 Variational equation constrained by the expectation value of particle number 2 2 vi i BCS eqs. Number eq. Gap eq. N 1 e v 1 ; E e 2 2 i 2 i i i 2 Ei G k 0 u v k k Fixed gaps taken from phenomenology 1 n B( N2, Z) 4 BN ( 1, Z) 6 BNZ (, ) 4 BN ( 1, Z) BN ( 2, Z) 8

1 E Vph r r 16 ( ) ( ) ph Residual interactions Particle-hole residual interaction consistent with the HF mean field 2 ss' tt' 1 ( 1) 1 2 1 ( 1) 1 2 1 2 sts'' t st r1 s ' t ' r2 2 1 ss' tt' E ( 1) ( 1) 1 21 2 1 2 16 sts'' t st ( r1 ) s ' t '( r2) V r r 1 2 2 2 4t 0 2t1kF 2t2kF t3 1212 r1r2 16 3 Average over nuclear volume Separable forces V 2 ( 1), t a a ph ph K GT GT K K K K K K 0, 1 pp 2 pp ( 1) K GT GT K K, K K K 0, 1 V P P P a a ph GT 3 1 2 1 3 t0 kf t1t2 t3 8 R 2 6

pnqrpa with separable forces Phonon operator pnqrpa equations K K X A Y A, A K K K K K K n p K 0 0, 0 K K K t M K K Transition amplitudes 0 K K K K M q X qy M q X q Y K K K q u v, q v u, K K K K Single-particle states from deformed Skyrme Hartree-Fock u, v: Occupation amplitudes from BCS pairing B(GT) in the lab. system IiKi00I fk f 1 K 2 2 0 0 0 1 1 1 B ( GT ) t 0 2 t 0

Stable nuclei in Fe-Ni mass region: Theory vs experiment Main constituents of stellar core in presupernovae. Comparison with : exp. (n,p), (p,n) SM calculations GT properties: Test of QRPA SM: NPA 653, 439 (1999) QRPA: NPA 716, 230 (2003)

Weak decay rates in pf-shell nuclei Calculations for several isotopes: Sc, Ti, V, Fe, Mn, Ni, Co, Zn exp: charge exchange reactions QRPA (n,p) B ( GT ) f t i if 2 Shell Model Accumulated GT strength A.L. Cole PRC 86, 015809 (2012) P.S. PRC87, 045801 (2013)

Weak decay rates in pf-shell nuclei, T P i ( T) B if if, T if Electron Capture from e - plasma cec 1( Q ) F( Z, ) S e if 2 2 if Se 1 S ( Qif ) d 1 exp e / kt 1 1 Q M M E E if 2 p d i f mc e Si burning Ia Supernova

Weak decay rates in pf-shell nuclei (Q<0) large: sensitive low-lying exc. P.S. PRC87, 045801 (2013)

Weak decay rates in pf-shell nuclei Q small

Exotic Nuclei : Nuclear Astrophysics X-ray bursts: Source of intense X-ray emissions generated by thermonuclear runaway in the H-rich environment of an accreting n-star, fed from a binary red giant companion. Nucleosynthesis mechanism: rp capture process rp-process: Proton capture reaction rates are orders of magitude faster than the competing -decays. Waiting point nuclei: When the dominant p-capture is inhibited, the reaction flow waits for a slow beta-decay to proceed further. Time scale Isotope abundances Light curve profile Tc (43) Mo (42) Nb (41) Zr (40) Y (39) Sr (38) Rb (37) Kr (36) Br (35) Se (34) As (33) Ge (32) Ga (31) Ag (47) Pd (46) Rh (45) Ru (44) 424344 272829303132333435363738394041 45464748 5455 53 5152 4950 56 5758 5

Medium mass neutron deficient isotopes Constrained HF+BCS Waiting point nuclei in rp-processes Shape coexistence Beyond full Shell Model

Gamow-Teller strength distribution Calculations for Ni, Zn, Ge, Se, Kr, Sr, Zr, Mo, Ru, Pd, Cd, Sn (N=Z and neighbors)

Gamow-Teller strength distribution

Gamow-Teller strength: Theory and Experiment ISOLDE: Total absorption spectroscopy Exp: Poirier et al. PRC69, 034307 (2004) Exp: Nacher et al. PRL92, 232501 (2004)

+ /EC half-lives: Theory and Experiment g / g 2 2 1 A V eff / EC 1/2 6200 f T f i g / g 0.74 g / g A V eff A V bare 1( Q ) F( Z, ) d if 1 Q if 2 2 if EC 2 2 2 2 qkgkbk ql g 1 L B 1 L 1 2 Good agreement with experiment: Reliable extrapolations to high and T

Weak decay rates in rp-process 74 Sr Deformed pn-qrpa B(GT) and T 1/2 : Good agreement with experiment Competition +/EC P.S. PRC83, 025801 (2011) 78 Sr

Weak decay rates in rp-process 74 Sr 76 Sr (WP) 78 Sr

Weak decay rates in rp-process 70 Kr (Large Q) P.S. Phys. Rev. C 83, 025801 (2011) 74 Kr (Small Q)

Weak decay rates in rp-process 70 Kr (Large Q) 72 Kr (WP) 74 Kr (Small Q)

Zr-Mo neutron-rich isotopes 100-116 Zr 104-120 Mo

Zr-Mo B(GT)

Zr-Mo B(GT)

Zr-Mo Half-lives

Shape dependence of GTdistributions in neutron-deficient Hg, Pb, Po isotopes... Triple shape coexistence at low excitation energy Search for signatures of deformation on their beta-decay patterns (MeV) 1 6 + 4 + 2 + 0 + 0 + 0 e - e - 0 + 186 Pb

Shape dependence of GTdistributions in neutron-deficient: Pb isotopes B(GT) strength distributions Not very sensitive to : Skyrme force and pairing treatment Sensitive to : Nuclear shape Signatures of deformation PRC 72, 054317 (2005), PRC 73, 054302 (2006) prolate oblate spherical QEC

Shape dependence of GTdistributions in neutron-deficient Hg, Po isotopes

Conclusions Nuclear structure model (deformed Skyrme HF+BCS+QRPA) o o Nuclear structure in different mass regions, astrophysical applications. Reproduce half-lives and main features of GT strength distributions extracted from beta-decay and/or charge exchange reactions. o Weak-decay rates at (,T) typical of astrophysical scenarios: pf-shell nuclei (presupernova): EC rates from QRPA comparable quality to benchmark SM calculations. Neutron-deficient WP nuclei (rp-process): EC/ + compete Neutron-rich Zr-Mo isotopes (r process).