6533b7d9fe1ef96bd126c0ef
RESEARCH PRODUCT
Description of the two-neutrino ββ decay of100Mo by pnMAVA
Jouni SuhonenJ. KotilaD. S. Delionsubject
PhysicsNuclear physicsNuclear and High Energy PhysicsProtonExcited stateDouble beta decayNuclear TheoryQuasiparticleNeutronNeutrinoNuclear ExperimentTransition rate matrixGround statedescription
The microscopic anharmonic vibrator approach (MAVA) is a scheme where the one- and two-phonon states of an even–even nucleus are treated consistently by using a realistic microscopic nuclear Hamiltonian. This model has recently been extended to describe odd–odd nuclei by adding proton–neutron phonons in a scheme called the proton–neutron MAVA (pnMAVA). In this paper, we apply pnMAVA to compute the nuclear matrix elements corresponding to the two-neutrino double beta (2νββ) decay of 100Mo to the ground state and the first excited 0+ state of 100Ru in a realistic single-particle space. We also compute the GT− and GT+ Gamow–Teller strength functions and compare them with the plain pnQRPA (proton–neutron QRPA) and available data. The redistribution of strength to four-quasiparticle degrees of freedom can be clearly seen in the GT+ function. The more striking effect is seen in the 2νββ matrix element corresponding to the ground-state transition where the incoherence of individual contributions is stronger for the pnMAVA than for the pnQRPA, and a 15% reduction in the magnitude of the matrix element is obtained for the pnMAVA. The 2νββ transition rate to the excited 0+ state is zero in a pnQRPA calculation, whereas the pnMAVA result is not far from the measured decay rate.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2009-11-23 | Journal of Physics G: Nuclear and Particle Physics |