微中子望遠鏡精確度的估計

Abstract

Neutrinos could play an important role in connecting several branches of particle astrophysics. The origin of ultra high energy cosmic ray (UHECR) is still a great puzzle. Bottom-up theories propose that they originate from energetic process such as Active Galactic Nuclei (AGN) or Gamma Ray Bursts (GRB). On the other hand, top-down theories suggest that UHECR are decay products of topological defects or heavy relic particles. Measurement of neutrino flux at and above the knee region (ie. $>10^{15}$ eV) provides a good discriminator to distinguish between the two scenarios. However, because of the extremely low flux (energy $>10^{15}$ eV) and small interaction cross section, conventional neutrino telescopes need detection volume in the order of km. Limited by dimension of detector volume, these detectors are sensitive at energy $<10^{15}$ eV. Ultra high energy cosmic ray detectors could detect neutrinos at energy above $10^{18}$ eV. The gap from $10^{15}$ to $10^{18}$ eV can be filled by our proposed neutrino telescope (NuTel). Using the earth or mountain as the target for converting neutrinos into leptons, we can detect the air shower initiated from the these leptons. Our goal is using the Monte-Carlo method to simulate the sensitivity of NuTel. First, we simulate the reaction of neu-tau in mountain. By considering the charge-current and neutral-current interactions, we can get the conversion rate of neu-tau to tau-lepton and the distribution function of the out-going tau energy. Second, we use the GIS terrain data to simulate some selected sites. Considering the tau decay length, Cherenkov light produced by air shower and adding the threshold of photon numbers of our telescope, we can get the acceptance. With the event rate 0.3/year/half decade of energy, we can estimate the sensitivity. Finally, we will make a comparison between different sites and between our NUTEL and other similar experiments.