The Pale Orange Dot: The Spectrum and Habitability of Hazy Archean Earth
550
Extraterrestrial Environment
Earth, Planet
QH301 Biology
Climate
Archean Earth
Astronomical Sciences
Planetary habitability
01 natural sciences
7. Clean energy
Theoretical
Models
SDG 13 - Climate Action
QB Astronomy
R2C
Research Articles
QB
Ultraviolet
Earth and Planetary Astrophysics (astro-ph.EP)
GE
Exoplanets
Temperature
Earth
Geology
Spectra
Spectrophotometry
Physical Sciences
Biosignatures
Gases
BDC
Space Sciences
Astronomical and Space Sciences
GE Environmental Sciences
Ultraviolet Rays
FOS: Physical sciences
Astronomy & Astrophysics
QH301
Exobiology
0103 physical sciences
Particle Size
Atmosphere
500
Water
DAS
Models, Theoretical
Climate Action
Geochemistry
13. Climate action
Astronomical sciences
Haze
Spectrophotometry, Ultraviolet
Planet
[PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]
Astrophysics - Earth and Planetary Astrophysics
DOI:
10.1089/ast.2015.1422
Publication Date:
2016-10-28T19:19:28Z
AUTHORS (9)
ABSTRACT
111 pages, 15 figures, 4 tables, accepted for publication in Astrobiology<br/>Recognizing whether a planet can support life is a primary goal of future exoplanet spectral characterization missions, but past research on habitability assessment has largely ignored the vastly different conditions that have existed in our planet's long habitable history. This study presents simulations of a habitable yet dramatically different phase of Earth's history, when the atmosphere contained a Titan-like organic-rich haze. Prior work has claimed a haze-rich Archean Earth (3.8-2.5 billion years ago) would be frozen due to the haze's cooling effects. However, no previous studies have self-consistently taken into account climate, photochemistry, and fractal hazes. Here, we demonstrate using coupled climate-photochemical-microphysical simulations that hazes can cool the planet's surface by about 20 K, but habitable conditions with liquid surface water could be maintained with a relatively thick haze layer (tau ~ 5 at 200 nm) even with the fainter young sun. We find that optically thicker hazes are self-limiting due to their self-shielding properties, preventing catastrophic cooling of the planet. Hazes may even enhance planetary habitability through UV shielding, reducing surface UV flux by about 97% compared to a haze-free planet, and potentially allowing survival of land-based organisms 2.6.2.7 billion years ago. The broad UV absorption signature produced by this haze may be visible across interstellar distances, allowing characterization of similar hazy exoplanets. The haze in Archean Earth's atmosphere was strongly dependent on biologically-produced methane, and we propose hydrocarbon haze may be a novel type of spectral biosignature on planets with substantial levels of CO2. Hazy Archean Earth is the most alien world for which we have geochemical constraints on environmental conditions, providing a useful analog for similar habitable, anoxic exoplanets.<br/>
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