Studying the physics potential of long-baseline experiments in terms of new sensitivity parameters

Abstract

We investigate physics opportunities to constraint leptonic CP-violation phase δCP through numerical analysis of working neutrino oscillation probability parameters, in the context of long base line experiments. Numerical analysis of two parameters, the " transition probability δCP phase sensitivity parameter (AM) " and " CP-violation probability δCP phase sensitivity parameter (ACP) ", as function of beam energy and/or base line has been preferably carried out. It is an elegant technique to broadly analyze different experiments to constraint δCP phase and also to investigate mass hierarchy in the leptonic sector. The positive and negative values of parameter ACP corresponding to either of hierarchy in the specific beam energy ranges, could be a very promising way to explore mass hierarchy and δCP phase. The keys to more robust bounds on δCP phase are improvements of the involved detection techniques to explore bit low energy and relatively long base line regions with better experimental accuracy.