Abstract
Paleo-detectors are a proposed experimental technique in which one would search for traces of recoiling nuclei in ancient minerals. Natural minerals on Earth are as old as $\mathcal{O}(1)\,$Gyr and, in many minerals, the damage tracks left by recoiling nuclei are also preserved for timescales long compared to 1 Gyr once created. Thus, even reading out relatively small target samples of order 100 g, paleo-detectors would allow one to search for very rare events thanks to the large exposure, $\varepsilon \sim 100\,{\rm g}\,{\rm Gyr} = 10^5\,{\rm t}\,{\rm yr}$. Here, we explore the potential of paleo-detectors to measure nuclear recoils induced by neutrinos from galactic core collapse supernovae. We find that they would not only allow for a direct measurement of the average core collapse supernova rate in the Milky Way, but would also contain information about the time-dependence of the local supernova rate over the past $\sim$1 Gyr. Since the supernova rate is thought to be directly proportional to the star formation rate, such a measurement would provide a determination of the local star formation history. We investigate the sensitivity of paleo-detectors to both a smooth time evolution and an enhancement of the core collapse supernova rate on relatively short timescales, as would be expected for a starburst period in the local group.
Highlights
Supernovae (SNe) play an important role in cosmology and astrophysics
We consider two distinct cases: (i) we study how well a smooth time evolution of the core collapse (CC) SN rate could be constrained by paleo detectors, and (ii) we investigate if paleodetectors could be used to find evidence for a starburst period in the Milky Way within the last ∼1 Gyr
We study the sensitivity of paleodetectors to both a single near-by CC SN and an enhancement of the CC SN rate which is localized in space and time, as would be expected from a starburst event in the Milky Way or the local group
Summary
Supernovae (SNe) play an important role in cosmology and astrophysics. For example, SN feedback is thought to be an important ingredient for understanding galaxy formation [1]. Paleodetectors could, for the first time, provide a direct measurement of the Galactic CC SN rate over the past ∼1 Gyr, as initially proposed in Ref. On the timescales relevant for paleodetectors (order 100 Myr and longer), the CC SN rate closely traces the star formation rate, see e.g. Refs. A direct measurement of the Galactic CC SN rate would provide valuable information for understanding our galaxy. Appendices A and B contain additional details about uranium-238 concentrations in typical target materials and the statistical techniques used in this work, respectively
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