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Bibliographic Details
Main Author: Kipping, David
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.01215
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author Kipping, David
author_facet Kipping, David
contents With no firm evidence for life beyond our solar system, inferences about the population observers such as ourselves rests upon the Earth as a single input, at least for now. Whilst the narrative of our home as a 'humdrum' system has become ingrained in the public psyche via Sagan, there are at least two striking facts about our existence which we know are certainly unusual. First, the stelliferous period spans ~10Tyr - yet here we are living in the first 0.1% of that volume. Second, over three-quarters of all stars are low-mass M-dwarfs, stars with no shortage of rocky habitable-zone planets - and yet, again, our existence defies this trend, previously dubbed the Red Sky Paradox. Two plausible resolutions are that a) stars below a certain mass, $M_{crit}$, do not produce observers, and, b) planets have a truncated temporal window for observers, $T_{win}$, negating the longevity advantage of M-dwarfs. We develop a Bayesian model that encompasses both datums and jointly explores the two resolutions covariantly. Our analysis reveals that 1) the hypothesis that these observations are mere luck is disfavored with an overwhelming Bayes factor of ~1600; 2) some truncation of low-mass stars is indispensable, lowering $T_{win}$ alone cannot well-explain the observations; and, 3) the most conservative limit on $M_{crit}$ occurs when fixing $T_{win}=10$Gyr, yielding $M_{crit}>0.34 M_{\odot}$ [$0.74 M_{\odot}$] to 2$σ$ [1$σ$]. Our work challenges the tacit assumption of M-dwarfs being viable seats for observers and, indirectly, even life.
format Preprint
id arxiv_https___arxiv_org_abs_2510_01215
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Solar Hegemony: M-Dwarfs Are Unlikely to Host Observers Such as Ourselves
Kipping, David
Instrumentation and Methods for Astrophysics
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
With no firm evidence for life beyond our solar system, inferences about the population observers such as ourselves rests upon the Earth as a single input, at least for now. Whilst the narrative of our home as a 'humdrum' system has become ingrained in the public psyche via Sagan, there are at least two striking facts about our existence which we know are certainly unusual. First, the stelliferous period spans ~10Tyr - yet here we are living in the first 0.1% of that volume. Second, over three-quarters of all stars are low-mass M-dwarfs, stars with no shortage of rocky habitable-zone planets - and yet, again, our existence defies this trend, previously dubbed the Red Sky Paradox. Two plausible resolutions are that a) stars below a certain mass, $M_{crit}$, do not produce observers, and, b) planets have a truncated temporal window for observers, $T_{win}$, negating the longevity advantage of M-dwarfs. We develop a Bayesian model that encompasses both datums and jointly explores the two resolutions covariantly. Our analysis reveals that 1) the hypothesis that these observations are mere luck is disfavored with an overwhelming Bayes factor of ~1600; 2) some truncation of low-mass stars is indispensable, lowering $T_{win}$ alone cannot well-explain the observations; and, 3) the most conservative limit on $M_{crit}$ occurs when fixing $T_{win}=10$Gyr, yielding $M_{crit}>0.34 M_{\odot}$ [$0.74 M_{\odot}$] to 2$σ$ [1$σ$]. Our work challenges the tacit assumption of M-dwarfs being viable seats for observers and, indirectly, even life.
title Solar Hegemony: M-Dwarfs Are Unlikely to Host Observers Such as Ourselves
topic Instrumentation and Methods for Astrophysics
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2510.01215