Search for the radiative decay of the cosmic neutrino background through spectral measurements of the cosmic infrared background using PRIMA

TL;DR

This paper proposes a spectral measurement method using PRIMA to detect or constrain the radiative decay of the cosmic neutrino background, which could reveal new physics and inform neutrino properties.

Contribution

It introduces a novel observational approach with spectral analysis to search for neutrino decay signals in the cosmic infrared background, extending lifetime sensitivity to 10^{15} years.

Findings

Potential to detect neutrino decay signals at 50 μm wavelength

Can constrain neutrino lifetimes up to 10^{15} years

Method could provide insights into neutrino mass and cosmology

Abstract

We propose to search for a faint yet distinguishable contribution to the cosmic infrared background (CIB) spectrum arising from the radiative decay of the cosmic neutrino background (C$\nu$B). In the Standard Model of particle physics, neutrino decay is highly suppressed, with a predicted lifetime on the order of $10^{43}$ years. However, non-standard models suggest the possibility of significantly shorter lifetimes, ranging from $10^{12}$ to $10^{17}$ years. Observations to date, however, only provide a lower limit of approximately $10^{12}$ years for the neutrino lifetime. In PRIMA's low-resolution mode ($R \sim 100$), a diffuse background analysis, combined with the removal of point sources associated with known galaxies in a wide-field ($\sim 1$ square degree) spectroscopic survey covering in the 24-240 $\mu$m range could facilitate a search for neutrino decay lifetimes up to $O(10^{15})$ years. The expected signal from C$\nu$B decay at 50 $\mu$m for a neutrino lifetime of $O(10^{15})$ years is more than an order of magnitude fainter than the CIB and over three orders of magnitude fainter than the zodiacal emission foreground. Taking advantage of the characteristic spectral features of C$\nu$B decay, this level of sensitivity can be achieved with approximately 100 hours of total observation time, based on estimated surface brightness sensitivity. Searching for neutrino decay at this sensitivity could place strong constraints on several non-standard theories. A positive detection would provide compelling evidence for non-standard contributions to neutrino decay and could directly reveal the cosmic neutrino background. Furthermore, the decay photon spectrum could offer insights into the absolute mass of neutrinos, and key cosmological parameters.