Radiation

Life in the Bubble: How a Nearby Supernova Left Ephemeral Footprints on the Cosmic-Ray Spectrum and Indelible Imprints on Life

By Keith Cowing

Status Report

IOPscience

March 9, 2025

Filed under 60Fe, astrochemistry, Interstellar, ionizing cosmic radiation, IOPscience, origin of life, Scorpius Centaurus, Spectroscopy, Supernova

Life in the Bubble: How a Nearby Supernova Left Ephemeral Footprints on the Cosmic-Ray Spectrum and Indelible Imprints on Life — The configuration of stellar associations in and around the LB. Left panel: shown is a projection (side view, horizontal being the Galactic plane) of today’s LB and the locations of the nearby stellar associations. The shape of the LB is taken from C. Zucker et al. (2022) and T. J. O’Neill et al. (2024). The shaded region illustrates the shell of dust surrounding the LB. The direction of the Galactic center (GC) is denoted by an arrow. Right panel: shown are the positions in Galactic coordinates of the nearby stellar associations Tuc-Hor and Sco-Cen’s subgroups: Lower Centaurus Crux, Upper Centaurus Lupus (UCL), and Upper Scorpius. Also shown (bubble) is the new Galactic bubble discovered by J. F. Robitaille et al. (2018), which is likely the remnant of an SN that took place in UCL. We anticipate an anisotropy in the distribution of arrival directions of cosmic rays that results from SN explosions hosted by these nearby stellar associations. — IOPscience

The Earth sits inside a 300 pc-wide void that was carved by a series of supernova explosions that went off tens of millions of years ago, pushing away interstellar gas and creating a bubble-like structure.

The 60Fe peak deposits found in the deep-sea crust have been interpreted by the imprints left by the ejecta of supernova explosions occurring about 2–3 and 5–6 Myr ago.

It is likely that the ⁶⁰Fe peak at about 2–3 Myr originated from a supernova occurring in the Upper Centaurus Lupus association in Scorpius Centaurus (≈140 pc) or the Tucana-Horologium association (≈70 pc), whereas the ≈5–6 Myr peak is likely attributed to the solar system’s entrance into the bubble.

In this Letter, we show that the supernova source responsible for synthesizing the ⁶⁰Fe peak deposits ≈2–3 Myr ago can consistently explain the cosmic-ray spectrum and the large-scale anisotropy between 100 TeV and 100 PeV. The cosmic-ray knee could then potentially be attributed entirely to a single nearby “PeVatron” source.

Matching the intensity and shape of the cosmic-ray spectrum allows us to place stringent constraints on the cosmic-ray energy content from the supernova as well as on the cosmic-ray diffusion coefficient.

Making use of such constraints, we provide a robust estimate of the temporal variation of terrestrial ionizing cosmic radiation levels and discuss their implications in the development of early life on Earth by plausibly influencing the mutation rate and, as such, conceivably assisting in the evolution of complex organisms.

Life in the Bubble: How a Nearby Supernova Left Ephemeral Footprints on the Cosmic-Ray Spectrum and Indelible Imprints on Life – IOPscience

Astrobiology,

Keith Cowing

Explorers Club Fellow, ex-NASA Space Station Payload manager/space biologist, Away Teams, Journalist, Lapsed climber, Synaesthete, Na’Vi-Jedi-Freman-Buddhist-mix, ASL, Devon Island and Everest Base Camp veteran, (he/him) 🖖🏻

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