Abstract
The discovery of amino acids in meteorites has presented two clues to the origin of their processing subsequent to their formation: a slight preference for left-handedness in some of them, and isotopic anomalies in some of their constituent atoms. In this article we present theoretical results from the Supernova Neutrino Amino Acid Processing (SNAAP) model, which uses electron anti-neutrinos and the magnetic fields from source objects such as supernovae or colliding neutron stars to selectively destroy one amino acid chirality and to create isotopic abundance shifts. For plausible magnetic fields and electron anti-neutrino fluxes, non-zero, positive enantiomeric excesses, $ee$s, defined to be the relative left/right asymmetry in an amino acid population, are reviewed for two amino acids, and conditions are suggested that would produce $ee>0$ for all of the $\alpha$-amino acids. The relatively high energy anti-neutrinos that produce the $ee$s would inevitably also produce isotopic anomalies. A nuclear reaction network was developed to describe the reactions resulting from them and the nuclides in the meteorites. At similar anti-neutrino fluxes, assumed recombination of the detritus from the anti-neutrino interactions is shown to produce appreciable isotopic anomalies in qualitative agreement with those observed for D/$^1$H and $^{15}$N/$^{14}$N. The isotopic anomalies for $^{13}$C/$^{12}$C are predicted to be small, as are also observed. Autocatalysis may be necessary for any model to produce the largest $ee$s observed in meteorites. This allows the constraints of the original SNAAP model to be relaxed, increasing the probability of meteoroid survival in sites where amino acid processing is possible. These results have obvious implications for the origin of life on Earth.
Highlights
One of the enduring mysteries in science has been the means by which Earthly amino acids have become nearly exclusively left-handed
II, we review the basic features of the supernova neutrino amino acid processing (SNAAP) model
Since the purpose of this paper is to explore how the SNAAP model can be enhanced with an autocatalytic mechanism and not the original SNAAP mechanism, the reader is referred to prior references
Summary
One of the enduring mysteries in science has been the means by which Earthly amino acids have become nearly exclusively left-handed. Meier [34], explored experimentally by Rikken and Raupach [35], and developed further by Barron [36] In this model, the interaction between photons from an intense light source, for example, a supernova, and molecules in a magnetic field, possibly from the supernova’s nascent neutron star or from a companion neutron star, would produce a chirality-dependent destruction effect on the amino acids. There are other explanations for the origin of a preferred amino acid chirality in outer space, we believe that they are less well developed than the CPL or MCA models [37,38], or the supernova neutrino amino acid processing (SNAAP) model [39,40,41], which appears able to explain how amino acids achieved left-handed chirality in outer space In this model, meteoric amino acids in magnetic fields are selectively destroyed via weak interactions with an external lepton flux.
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