The Project 8 Neutrino Mass Experiment

Authors :: Project 8 Collaboration
Esfahani, A. Ashtari
Böser, S.
Buzinsky, N.
Carmona-Benitez, M. C.
Claessens, C.
de Viveiros, L.
Doe, P. J.
Enomoto, S.
Fertl, M.
Formaggio, J. A.
Gaison, J. K.
Grando, M.
Heeger, K. M.
Huyan, X.
Jones, A. M.
Kazkaz, K.
Li, M.
Lindman, A.
Matthé, C.
Mohiuddin, R.
Monreal, B.
Mueller, R.
Nikkel, J. A.
Novitski, E.
Oblath, N. S.
Peña, J. I.
Pettus, W.
Reimann, R.
Robertson, R. G. H.
Rybka, G.
Saldaña, L.
Schram, M.
Slocum, P. L.
Stachurska, J.
Sun, Y. -H.
Surukuchi, P. T.
Tedeschi, J. R.
Telles, A. B.
Thomas, F.
Thomas, M.
Thorne, L. A.
Thümmler, T.
Van De Pontseele, W.
VanDevender, B. A.
Weiss, T. E.
Wendler, T.
Ziegler, A.
Publication Year :: 2022
Abstract: Measurements of the $\beta^-$ spectrum of tritium give the most precise direct limits on neutrino mass. Project 8 will investigate neutrino mass using Cyclotron Radiation Emission Spectroscopy (CRES) with an atomic tritium source. CRES is a new experimental technique that has the potential to surmount the systematic and statistical limitations of current-generation direct measurement methods. Atomic tritium avoids an irreducible systematic uncertainty associated with the final states populated by the decay of molecular tritium. Project 8 will proceed in a phased approach toward a goal of 40 meV/c$^2$ neutrino-mass sensitivity.<br />Comment: contribution to Snowmass 2021

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