Nuria López Vaquero, Tomás R. Rodríguez, J. Luis Egido
Published 2014-01-03Version 1
Nuclear matrix elements (NME) for the most promising candidates to detect neutrinoless double beta decay have been computed with energy density functional methods including deformation and pairing fluctuations explicitly on the same footing. The method preserves particle number and angular momentum symmetries and can be applied to any decay without additional fine tunings. The finite range density dependent Gogny force is used in the calculations. An increase of $10\%-40\%$ in the NME with respect to the ones found without the inclusion of pairing fluctuations is obtained, reducing the predicted half-lives of these isotopes.
Comments: 5 pages, 3 Figures
Journal: Phys. Rev. Lett. 111, 142501 (2013)
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