Optimized Two-Baseline Beta-Beam Experiment

TL;DR

This paper proposes an optimized two-baseline Beta-Beam experiment with enhanced ion boost factors and magnetic field strengths, aiming to improve sensitivity to neutrino oscillation parameters while reducing infrastructure challenges.

Contribution

It introduces a method to trade decay ring livetime for higher ion boost factors, reducing maximum decay ring depth without sacrificing experimental sensitivity.

Findings

Enhanced sensitivity to theta_{13}, CP violation, and mass hierarchy.

Reduced decay ring depth with increased ion boost and magnetic field.

Comparable or improved performance relative to other proposed facilities.

Abstract

We propose a realistic Beta-Beam experiment with four source ions and two baselines for the best possible sensitivity to theta_{13}, CP violation and mass hierarchy. Neutrinos from 18Ne and 6He with Lorentz boost gamma=350 are detected in a 500 kton water Cerenkov detector at a distance L=650 km (first oscillation peak) from the source. Neutrinos from 8B and 8Li are detected in a 50 kton magnetized iron detector at a distance L=7000 km (magic baseline) from the source. Since the decay ring requires a tilt angle of 34.5 degrees to send the beam to the magic baseline, the far end of the ring has a maximum depth of d=2132 m for magnetic field strength of 8.3 T, if one demands that the fraction of ions that decay along the straight sections of the racetrack geometry decay ring (called livetime) is 0.3. We alleviate this problem by proposing to trade reduction of the livetime of the decay ring with the increase in the boost factor of the ions, such that the number of events at the detector remains almost the same. This allows to substantially reduce the maximum depth of the decay ring at the far end, without significantly compromising the sensitivity of the experiment to the oscillation parameters. We take 8B and 8Li with gamma=390 and 656 respectively, as these are the largest possible boost factors possible with the envisaged upgrades of the SPS at CERN. This allows us to reduce d of the decay ring by a factor of 1.7 for 8.3 T magnetic field. Increase of magnetic field to 15 T would further reduce d to 738 m only. We study the sensitivity reach of this two baseline two storage ring Beta-Beam experiment, and compare it with the corresponding reach of the other proposed facilities.