A Diffraction Grating for the Cosmic Neutrino Background and Dark Matter

TL;DR

This paper proposes a novel diffraction grating structure that significantly enhances local neutrino and dark matter asymmetries, potentially enabling new detection methods for the cosmic neutrino background and dark matter particles.

Contribution

It introduces a new diffraction grating design that amplifies neutrino and dark matter signals, offering a potential pathway for their detection.

Findings

Neutrino asymmetry can be enhanced by up to 10^6 times.

The resulting force on a test mass could approach the Standard Quantum Limit.

Dark matter diffraction could produce forces 100 times larger than neutrino effects.

Abstract

We propose structures of size between $\sim 1$ meter to 100 meters that drastically alter the local distribution of the Cosmic Neutrino Background ($C\nu B$). These structures have a shape reminiscent of a sea urchin: They consist of rods of width $w$ and length $L \gg w$ periodically arranged on the surface of sphere of radius $R\sim L$. Such a structure functions as a diffraction phase grating and produces a region around its center where the fractional neutrino-antineutrino asymmetry is $\sim k\delta_\nu L$, where $k$ is the neutrino momentum, and $\delta_\nu$ the deviation of the neutrino index of refraction from unity. The asymmetry has a gradient set by the rod width. We find that the local neutrino asymmetry can be enhanced by $\mathcal{O}(\text{few}\times 10^6)$ relative to the naive Standard Model expectation, for reasonably sized structures. This results in a force $\mathcal{O}(10^3)$ times bigger than the one we recently pointed out due to the neutrinos' reflection on the surface of the Earth. While in this paper we do not propose a concrete detection setup, we estimate that the $\mathcal{O}(G_F)$ force on a test mass can be close to the Standard Quantum Limit of a torsion balance or a low frequency harmonic oscillator. Finally, we show that this $C \nu B$ diffractor can be used as a Dark Matter diffractor. For example, the QCD axion Dark Matter with decay constant $f_a$ around $10^9$ GeV can be sufficiently diffracted to produce a gradient force that is up to $\mathcal{O}(10^2)$ times larger than the one from the $C \nu B$. This is the first setup of this kind and the simplicity of our design suggests that there could be significant improvements that escape us.