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Radiolysis Generates a Complex Organosynthetic Chemical Network

submitted on 04.11.2019, 18:09 and posted on 13.11.2019, 00:00 by Zachary Adam, Albert C. Fahrenbach, Sofia Marie Jacobson, Betul Kacar, Dmitry Yu. Zubarev

Origins of life chemistry has progressed from seeking out the production of specific molecules to seeking out conditions in which macromolecular precursors may interact with one another in ways that lead to biological organization. Reported precursor synthesis networks generally lack biological organizational attributes. Radical species are highly reactive, but do their chemical reaction networks resemble living systems? Here we report the results of radiolysis reaction experiments that connect abundant geochemical reservoirs to the production of carboxylic acids, amino acids, and ribonucleotide precursors and study the topological properties of the resulting network. The network exhibits attributes associated with biological systems: it is hierarchically organized, there are families of closed loop cycles, and the species and cycle histograms exhibit heterogeneous (heavy-tailed) distributions. The core cycles of the network are made possible by the high reactivity of radical species such as H and OH. Radiolysis is implicated as a unique prerequisite for driving abiotic organosynthetic self-organization.


Simons Collaboration on the Origins of Life (494291)

National Science Foundation (1724090)

John Templeton Foundation (58562)

John Templeton Foundation (61239)


Email Address of Submitting Author


University of Arizona


United States of America

ORCID For Submitting Author


Declaration of Conflict of Interest

No conflict of interest.

Version Notes

version 2.5


Read the published paper

in Scientific Reports

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