Abstract:
The λ and mββ mechanisms of neutrinoless double beta decay (0νββ) occur with light neutrino
exchange via WL − WR, and WL − WL mediation, respectively. In the present study, we calculate
the nuclear matrix elements (NMEs) for the mββ and λ mechanisms of 0νββ, which has origin in the
left-right symmetric model with right-handed gauge boson at TeV scale. The NMEs are calculated
for one of the 0νββ decaying isotope 48Ca in the interacting nuclear shell-model using the GXPF1A
effective interaction of pf-shell. The NMEs are calculated in both closure and nonclosure approaches
using four different methods: closure, running closure, running nonclosure, and mixed methods. All
the NMEs are calculated incorporating the effects of the finite size of nucleons and the revisited
higher order terms such as isoscalar and weak magnetism terms of the nucleon currents. Inclusion
of the short-range nature of nucleon-nucleon interaction in Miller-Spencer, CD-Bonn, and AV18
parametrizations is also taken care of. The comparative dependence of the running closure and
running nonclosure NMEs with the spin-parity of the allowed states of intermediate nucleus 48Sc,
the coupled spin-parity of the two initial decaying neutrons and the final two protons, the cutoff
excitation energy of 48Sc, the cutoff number of states of 48Sc are also examined. Results show that
there are about 2-20% enhancements in different types of total NMEs, calculated in the nonclosure
approach as compared to the closure approach. The significant enhancements are found in the MqGT
and MqT type NMEs for the inclusion of the higher-order terms of the nucleon currents.
