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Physics Opportunities with PROSPECT-II

High Energy Physics - Experiment 2022-07-15 v2 Nuclear Experiment

Abstract

The PROSPECT experiment has substantially addressed the original 'Reactor Antineutrino Anomaly' by performing a high-resolution spectrum measurement from an enriched compact reactor core and a reactor model-independent sterile neutrino oscillation search based on the unique spectral distortions the existence of eV2^2-scale sterile neutrinos would impart. But as the field has evolved, the current short-baseline (SBL) landscape supports many complex phenomenological interpretations, establishing a need for complementary experimental approaches to resolve the situation. While the global suite of SBL reactor experiments, including PROSPECT, have probed much of the sterile neutrino parameter space, there remains a large region above 1 eV2^2 that remains unaddressed. Recent results from BEST confirm the Gallium Anomaly, increasing its significance to 5σ\sim 5\sigma, with sterile neutrinos providing a possible explanation of this anomaly. Separately, the MicroBooNE exclusion of electron-like signatures causing the MiniBooNE low-energy excess does not eliminate the possibility of sterile neutrinos as an explanation. Focusing specifically on the future use of reactors as a neutrino source for beyond-the-standard-model physics and applications, higher-precision spectral measurements still have a role to play. These recent results have created a confusing landscape which requires new data to disentangle the seemingly contradictory measurements. To directly probe νe\overline{\nu}_{e} disappearance from high Δm2\Delta m^2 sterile neutrinos, the PROSPECT collaboration proposes to build an upgraded and improved detector, PROSPECT-II. It features an evolutionary detector design which can be constructed and deployed within one year and have impactful physics with as little as one calendar year of data.

Keywords

Cite

@article{arxiv.2202.12343,
  title  = {Physics Opportunities with PROSPECT-II},
  author = {M. Andriamirado and A. B. Balantekin and C. D. Bass and D. E. Bergeron and E. Bernard and N. S. Bowden and C. D. Bryan and R. Carr and T. Classen and A. J. Conant and G. Deichert and A. Delgado and M. V. Diwan and M. J. Dolinski and A. Erickson and B. T. Foust and J. K. Gaison and A. Galindo-Uribari and C. E. Gilbert and S. Gokhale and C. Grant and S. Hans and A. B. Hansell and K. M. Heeger and B. Heffron and D. E. Jaffe and S. Jayakumar and X. Ji and D. C. Jones and J. Koblanski and P. Kunkle and O. Kyzylova and C. E. Lane and T. J. Langford and J. LaRosa and B. R. Littlejohn and X. Lu and J. Maricic and M. P. Mendenhall and A. M. Meyer and R. Milincic and P. E. Mueller and H. P. Mumm and J. Napolitano and R. Neilson and J. A. Nikkel and S. Nour and J. L. Palomino and D. A. Pushin and X. Qian and C. Roca and R. Rosero and M. Searles and P. T. Surukuchi and F. Sutanto and M. A. Tyra and R. L. Varner and D. Venegas-Vargas and P. B. Weatherly and J. Wilhelmi and A. Woolverton and M. Yeh and C. Zhang and X. Zhang},
  journal= {arXiv preprint arXiv:2202.12343},
  year   = {2022}
}

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contribution to Snowmass 2021

R2 v1 2026-06-24T09:52:59.936Z