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Amateur telescopes discover a kilometre-sized Kuiper belt object from stellar occultation

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arxiv 1910.09994 v1 pith:T7Z457RC submitted 2019-10-22 astro-ph.EP astro-ph.IM

Amateur telescopes discover a kilometre-sized Kuiper belt object from stellar occultation

classification astro-ph.EP astro-ph.IM
keywords kboskilometre-sizedoccultationbeltdetectiondistributionkuiperradius
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Kuiper belt objects (KBOs) are thought to be the remnant of the early solar system, and their size distribution provides an opportunity to explore the formation and evolution of the outer solar system. In particular, the size distribution of kilometre-sized (radius = 1-10 km) KBO represents a signature of initial planetesimal sizes when planets form. These kilometre-sized KBOs are extremely faint, and it is impossible to detect them directly. Instead, monitoring of stellar occultation events is one possible way to discover these small KBOs. Hitherto, however, there has been no observational evidence for the occultation events by KBOs with radii of 1-10 km. Here we report the first detection of a single occultation event candidate by a KBO with a radius of $\sim$1.3 km, which is simultaneously provided by two low-cost small telescopes coupled with commercial CMOS cameras. From this detection, we conclude that a surface number density of KBOs with radii exceeding $\sim 1.2$ km is $\sim 6 \times 10^5 \ {\rm deg^{-2}}$. This surface number density favours a theoretical size distribution model with an excess signature at a radius of 1-2 km. If this is a true detection, this implies that planetesimals before their runaway growth phase grow into kilometre-sized objects in the primordial outer solar system and remain as a major population of the present-day Kuiper belt.

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