The Improved Measurement of Electron-antineutrino Disappearance at Daya Bay

TL;DR

The Daya Bay experiment's enhanced measurement with increased exposure has refined the value of the neutrino mixing parameter sin^2(2theta_13), confirming reactor anti-neutrino disappearance with high precision.

Contribution

This work provides the most precise measurement of theta_13 using an improved experimental setup and larger data set compared to previous studies.

Findings

Measured sin^2(2theta_13) = 0.089+-0.010(stat)+-0.005(syst)

Detected 234,217 anti-neutrino candidates in 127 days

Achieved background levels of 5% and 2% in far and near detectors

Abstract

With 2.5x the previously reported exposure, the Daya Bay experiment has improved the measurement of the neutrino mixing parameter sin^2(2theta_13) = 0.089+-0.010(stat)+-0.005(syst). Reactor anti-neutrinos were produced by six 2.9 GW(th) commercial power reactors, and measured by six 20-ton target-mass detectors of identical design. A total of 234,217 anti-neutrino candidates were detected in 127 days of exposure. An anti-neutrino rate of 0.944+-0.007(stat)+-0.003(syst) was measured by three detectors at a flux-weighted average distance of 1648 m from the reactors, relative to two detectors at 470 m and one detector at 576 m. Detector design and depth underground limited the background to 5+-0.3% (far detectors) and 2+-0.2% (near detectors) of the candidate signals. The improved precision confirms the initial measurement of reactor anti-neutrino disappearance, and continues to be the most precise measurement of theta_13.