The rapid formation of macromolecules in irradiated ice of protoplanetary disk dust traps
N. F.W. Ligterink (University of Bern, TU Delft - Planetary Exploration)
Paola Pinilla (MSSL/UCL)
Nienke van der Marel (Universiteit Leiden)
Jeroen Terwisscha Van Scheltinga (Universiteit Leiden)
Alice S. Booth (Universiteit Leiden, Harvard-Smithsonian Center for Astrophysics)
Conel M.O.D. Alexander (Carnegie Institution for Science)
My E.I. Riebe (ETH Zürich)
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Abstract
Organic macromolecular matter is the dominant carrier of volatile elements such as carbon, nitrogen and noble gases in chondrites—the rocky building blocks from which Earth formed. How this macromolecular substance formed in space is unclear. Here we show that its formation could be associated with the presence of dust traps, which are prominent mechanisms for forming planetesimals in planet-forming disks. We demonstrate the existence of heavily irradiated zones in dust traps, where small frozen molecules that coat large quantities of microscopic dust grains could be rapidly converted into macromolecular matter by receiving radiation doses of up to several tens of electronvolts per molecule per year. This allows for the transformation of simple molecules into complex macromolecular matter within several decades. Up to roughly 4% of the total disk ice reservoir can be processed this way and subsequently incorporated into the protoplanetary disk midplane where planetesimals form. This finding shows that planetesimal formation and the production of organic macromolecular matter, which provides the essential elemental building blocks for life, might be linked.