Add to ORKGWe derive the character of neutrino oscillations that results from a model of equivalence principle violation suggested recently by Damour and Polyakov as a plausible consequence of string theory. In this model neutrino oscillations will take place through interaction with a long range scalar field of gravitational origin even if the neutrinos are degenerate in mass. The energy dependence of the oscillation length is identical to that in the conventional mass mixing mechanism. This possibility further highlghts the independence of and need for more exacting direct neutrino mass measurements together with a next generation of neutrinoless double beta decay experiments
Neutrinos are very light fermions, which have three flavour states and three mass states. Being neut...
Both gravitational and mass induced neutrino oscillation mechanisms provide possible resolutions to ...
Flavor oscillations of neutrinos are analyzed in the framework of Brans-Dicke theory of gravity. We ...
We examine the possible tests of violation of the gravitational equivalence principle (VEP) at a muo...
We consider the hypothesis that neutrino oscillation data can be explained if the gravitational coup...
We consider the unconventional way to interpret the current data on solar neutrino oscillations as d...
We have reexamined the possibility of explaining the solar neutrino problem through long-wavelength ...
We introduce a new effect in the neutrino oscillation phase which shows the neutrino-antineutrino os...
We study neutrino oscillations within the framework of extended theories of gravity. Based on the co...
We show that under gravity the effective masses for neutrino and antineutrino are different which op...
We consider the effect of a long range, flavor changing tensor interaction of possible gravitational...
Quantum gravitational fluctuations of the space-time background, described by virtual D branes, may ...
The Sudbury Neutrino Observatory (SNO) result on charged current deuteron disintegration, the Super ...
Recent studies of neutrino oscillations have established the existence of finite neutrino masses an...
The SNO result on charged current deuteron disintegration, the SuperKamiokande 1258-day data on elec...
Neutrinos are very light fermions, which have three flavour states and three mass states. Being neut...
Both gravitational and mass induced neutrino oscillation mechanisms provide possible resolutions to ...
Flavor oscillations of neutrinos are analyzed in the framework of Brans-Dicke theory of gravity. We ...
We examine the possible tests of violation of the gravitational equivalence principle (VEP) at a muo...
We consider the hypothesis that neutrino oscillation data can be explained if the gravitational coup...
We consider the unconventional way to interpret the current data on solar neutrino oscillations as d...
We have reexamined the possibility of explaining the solar neutrino problem through long-wavelength ...
We introduce a new effect in the neutrino oscillation phase which shows the neutrino-antineutrino os...
We study neutrino oscillations within the framework of extended theories of gravity. Based on the co...
We show that under gravity the effective masses for neutrino and antineutrino are different which op...
We consider the effect of a long range, flavor changing tensor interaction of possible gravitational...
Quantum gravitational fluctuations of the space-time background, described by virtual D branes, may ...
The Sudbury Neutrino Observatory (SNO) result on charged current deuteron disintegration, the Super ...
Recent studies of neutrino oscillations have established the existence of finite neutrino masses an...
The SNO result on charged current deuteron disintegration, the SuperKamiokande 1258-day data on elec...
Neutrinos are very light fermions, which have three flavour states and three mass states. Being neut...
Both gravitational and mass induced neutrino oscillation mechanisms provide possible resolutions to ...
Flavor oscillations of neutrinos are analyzed in the framework of Brans-Dicke theory of gravity. We ...