A New Fit to Solar Neutrinos Using Extra Dimensions
Abstract
A neutrino mass-mixing scheme which explains qualitatively all present evidence for neutrino mass (the solar and atmospheric neutrino deficits, LSND, and hot dark matter), and also makes possible heavy-element nucleosynthesis by supernovae, requires at least one light sterile neutrino. String-inspired models with sub-millimeter extra dimensions provide naturally light sterile neutrinos, as is needed to explain the solar nue deficit. This bulk sterile neutrino provides a better fit to the solar data than conventional models by having vacuum oscillations of the nue to its zero mode and MSW oscillations to its first few Kaluza-Klein modes. While the prediction of the Super-Kamiokande energy spectrum gives a fit probability of 73%, the superior energy resolution of SNO's charged-current spectrum will determine whether this neutrino scheme is correct and can demonstrate that an extra dimension of ~60 mu m exists. Should this be the case, there are important implications for supernovae, ultra-high-energy cosmic rays, double beta decay, and dark matter.
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