Cosmic Rays Might Explain Structural Preferences of Early Life on Earth, New Study Finds

Scientists have long been puzzled by the existence of “the handedness of life” or the fact that molecules have the same chirality, meaning they reflect each other in shape. Now, we might have gotten closer to finding the answer to what caused such a dramatic organisation of nature.

Physicists propose that it is influence of cosmic rays on antient proto-organisms in the early stages of life’s development on Earth that may explain the existence of chirality in critical biological molecules, a new study published by the Astrophysical Journal Letters reveals.

Chirality or “handedness” of molecules signify the presence of their mirror-like reflections, allowing for the creation of more stable DNA, RNA and amino acids compounds if the regular version of molecules, and not their mirror version, are adopted within the structures. The biological homochirality was first studied in 1848 by Lois Pasteur and since then, scientists have been trying to solve the puzzle explaining the origin of chiral preferences for only one particular form of handedness.

Researchers from Stanford and New York University now say the cosmos is to blame.

It is cosmic rays, originating from various properties around the universe, including stars, that have bombarded our planet’s atmosphere in its early stages to create such a dramatic effect. On the Earth’s level, rays were breaking into particles, known as muons, to eventually influence the evolution of two “mirror-life forms” on our planet differently, with one prevailing over another due to consistent radiation.

Meanwhile, the hypothesis, supported by a series of proposed experiments, could mean something more significant if correct – mainly that it is not only molecules on the Earth that share the same chiral preference, but also all potential life forms in our universe.


Cosmic Rays Might Explain Structural Preferences of Early Life on Earth, New Study Finds

0.00 (0%) 0 votes