Probes of Lorentz Violation in Neutrino Propagation

Abstract

It has been suggested that the interactions of energetic particles with the foamy structure of space-time thought to be generated by quantum-gravitational (QG) effects might violate Lorentz invariance, so that they do not propagate at a universal speed of light. We consider the limits that may be set on a linear or quadratic violation of Lorentz invariance in the propagation of energetic neutrinos, v/c=[1 +- (E/M1)] or [1 +- (E/M QG22], using data from supernova explosions and the OPERA long-baseline neutrino experiment. Using the SN1987a neutrino data from the Kamioka II, IMB and Baksan experiments, we set the limits M1 > 2.7(2.5)x1010 GeV for subluminal (superluminal) propagation, respectively, and M2 >4.6(4.1)x104 GeV at the 95% confidence level. A future galactic supernova at a distance of 10 kpc would have sensitivity to M1 > 2(4)x1011 GeV for subluminal (superluminal) propagation, respectively, and M2 > 2(4)x105 GeV. With the current CNGS extraction spill length of 10.5 micro seconds and with standard clock synchronization techniques, the sensitivity of the OPERA experiment would reach M1 ~ 7x105 GeV (M2 ~ 8x103 GeV) after 5 years of nominal running. If the time structure of the SPS RF bunches within the extracted CNGS spills could be exploited, these figures would be significantly improved to M1 ~ 5x107 GeV (M2 ~ 4x104 GeV). These results can be improved further if similar time resolution can be achieved with neutrino events occurring in the rock upstream of the OPERA detector: we find potential sensitivities to M1 ~ 4x108 GeV and M2 ~ 7x105 GeV.