Emergence of a habitable planet

Kevin Zahnle; Nick Arndt; Charles S. Cockell; Alex Halliday; Euan Nisbet; Franck Selsis; Norman H. Sleep

doi:10.1007/s11214-007-9225-z

Emergence of a habitable planet

Kevin Zahnle^*, Nick Arndt, Charles S. Cockell, Alex Halliday, Euan Nisbet, Franck Selsis, Norman H. Sleep

^*Corresponding author for this work

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

We address the first several hundred million years of Earth's history. The Moon-forming impact left Earth enveloped in a hot silicate atmosphere that cooled and condensed over similar to 1,000 yrs. As it cooled the Earth degassed its volatiles into the atmosphere. It took another similar to 2 Myrs for the magma ocean to freeze at the surface. The cooling rate was determined by atmospheric thermal blanketing. Tidal heating by the new Moon was a major energy source to the magma ocean. After the mantle solidified geothermal heat became climatologically insignificant, which allowed the steam atmosphere to condense, and left behind a similar to 100 bar, similar to 500 K CO(2) atmosphere. Thereafter cooling was governed by how quickly CO(2) was removed from the atmosphere. If subduction were efficient this could have taken as little as 10 million years. In this case the faint young Sun suggests that a lifeless Earth should have been cold and its oceans white with ice. But if carbonate subduction were inefficient the CO(2) would have mostly stayed in the atmosphere, which would have kept the surface near similar to 500 K for many tens of millions of years. Hydrous minerals are harder to subduct than carbonates and there is a good chance that the Hadean mantle was dry. Hadean heat flow was locally high enough to ensure that any ice cover would have been thin (<5 m) in places. Moreover hundreds or thousands of asteroid impacts would have been big enough to melt the ice triggering brief impact summers. We suggest that plate tectonics as it works now was inadequate to handle typical Hadean heat flows of 0.2-0.5 W/m(2). In its place we hypothesize a convecting mantle capped by a similar to 100 km deep basaltic mush that was relatively permeable to heat flow. Recycling and distillation of hydrous basalts produced granitic rocks very early, which is consistent with preserved > 4 Ga detrital zircons. If carbonates in oceanic crust subducted as quickly as they formed, Earth could have been habitable as early as 10-20 Myrs after the Moon-forming impact.

Original language	English
Pages (from-to)	35-78
Number of pages	44
Journal	Space Science Reviews
Volume	129
Issue number	1-3
DOIs	https://doi.org/10.1007/s11214-007-9225-z
Publication status	Published - Mar 2007
Event	Workshop on Geology and Habitability of Terrestrial Planets - Bern, Switzerland Duration: 5 Sept 2005 → 9 Sept 2005

Keywords / Materials (for Non-textual outputs)

hadean earth
moon-forming impact
origin of earth
magma oceans
planetary atmospheres
late heavy bombardment
LATE HEAVY BOMBARDMENT
INNER SOLAR-SYSTEM
HF-W CHRONOMETRY
PRIMORDIAL TERRESTRIAL ATMOSPHERE
EARLY CORE FORMATION
EARTH-MOON SYSTEM
FRONT FACE BASINS
CONTINENTAL-CRUST
ISOTOPE SYSTEMATICS
DETRITAL ZIRCONS

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10.1007/s11214-007-9225-z

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@article{82db53ad8a5e447990809ccab74018df,

title = "Emergence of a habitable planet",

abstract = "We address the first several hundred million years of Earth's history. The Moon-forming impact left Earth enveloped in a hot silicate atmosphere that cooled and condensed over similar to 1,000 yrs. As it cooled the Earth degassed its volatiles into the atmosphere. It took another similar to 2 Myrs for the magma ocean to freeze at the surface. The cooling rate was determined by atmospheric thermal blanketing. Tidal heating by the new Moon was a major energy source to the magma ocean. After the mantle solidified geothermal heat became climatologically insignificant, which allowed the steam atmosphere to condense, and left behind a similar to 100 bar, similar to 500 K CO(2) atmosphere. Thereafter cooling was governed by how quickly CO(2) was removed from the atmosphere. If subduction were efficient this could have taken as little as 10 million years. In this case the faint young Sun suggests that a lifeless Earth should have been cold and its oceans white with ice. But if carbonate subduction were inefficient the CO(2) would have mostly stayed in the atmosphere, which would have kept the surface near similar to 500 K for many tens of millions of years. Hydrous minerals are harder to subduct than carbonates and there is a good chance that the Hadean mantle was dry. Hadean heat flow was locally high enough to ensure that any ice cover would have been thin (<5 m) in places. Moreover hundreds or thousands of asteroid impacts would have been big enough to melt the ice triggering brief impact summers. We suggest that plate tectonics as it works now was inadequate to handle typical Hadean heat flows of 0.2-0.5 W/m(2). In its place we hypothesize a convecting mantle capped by a similar to 100 km deep basaltic mush that was relatively permeable to heat flow. Recycling and distillation of hydrous basalts produced granitic rocks very early, which is consistent with preserved > 4 Ga detrital zircons. If carbonates in oceanic crust subducted as quickly as they formed, Earth could have been habitable as early as 10-20 Myrs after the Moon-forming impact.",

keywords = "hadean earth, moon-forming impact, origin of earth, magma oceans, planetary atmospheres, late heavy bombardment, LATE HEAVY BOMBARDMENT, INNER SOLAR-SYSTEM, HF-W CHRONOMETRY, PRIMORDIAL TERRESTRIAL ATMOSPHERE, EARLY CORE FORMATION, EARTH-MOON SYSTEM, FRONT FACE BASINS, CONTINENTAL-CRUST, ISOTOPE SYSTEMATICS, DETRITAL ZIRCONS",

author = "Kevin Zahnle and Nick Arndt and Cockell, {Charles S.} and Alex Halliday and Euan Nisbet and Franck Selsis and Sleep, {Norman H.}",

year = "2007",

month = mar,

doi = "10.1007/s11214-007-9225-z",

language = "English",

volume = "129",

pages = "35--78",

journal = "Space Science Reviews",

issn = "0038-6308",

publisher = "Springer",

number = "1-3",

note = "Workshop on Geology and Habitability of Terrestrial Planets ; Conference date: 05-09-2005 Through 09-09-2005",

}

TY - JOUR

T1 - Emergence of a habitable planet

AU - Zahnle, Kevin

AU - Arndt, Nick

AU - Cockell, Charles S.

AU - Halliday, Alex

AU - Nisbet, Euan

AU - Selsis, Franck

AU - Sleep, Norman H.

PY - 2007/3

Y1 - 2007/3

N2 - We address the first several hundred million years of Earth's history. The Moon-forming impact left Earth enveloped in a hot silicate atmosphere that cooled and condensed over similar to 1,000 yrs. As it cooled the Earth degassed its volatiles into the atmosphere. It took another similar to 2 Myrs for the magma ocean to freeze at the surface. The cooling rate was determined by atmospheric thermal blanketing. Tidal heating by the new Moon was a major energy source to the magma ocean. After the mantle solidified geothermal heat became climatologically insignificant, which allowed the steam atmosphere to condense, and left behind a similar to 100 bar, similar to 500 K CO(2) atmosphere. Thereafter cooling was governed by how quickly CO(2) was removed from the atmosphere. If subduction were efficient this could have taken as little as 10 million years. In this case the faint young Sun suggests that a lifeless Earth should have been cold and its oceans white with ice. But if carbonate subduction were inefficient the CO(2) would have mostly stayed in the atmosphere, which would have kept the surface near similar to 500 K for many tens of millions of years. Hydrous minerals are harder to subduct than carbonates and there is a good chance that the Hadean mantle was dry. Hadean heat flow was locally high enough to ensure that any ice cover would have been thin (<5 m) in places. Moreover hundreds or thousands of asteroid impacts would have been big enough to melt the ice triggering brief impact summers. We suggest that plate tectonics as it works now was inadequate to handle typical Hadean heat flows of 0.2-0.5 W/m(2). In its place we hypothesize a convecting mantle capped by a similar to 100 km deep basaltic mush that was relatively permeable to heat flow. Recycling and distillation of hydrous basalts produced granitic rocks very early, which is consistent with preserved > 4 Ga detrital zircons. If carbonates in oceanic crust subducted as quickly as they formed, Earth could have been habitable as early as 10-20 Myrs after the Moon-forming impact.

AB - We address the first several hundred million years of Earth's history. The Moon-forming impact left Earth enveloped in a hot silicate atmosphere that cooled and condensed over similar to 1,000 yrs. As it cooled the Earth degassed its volatiles into the atmosphere. It took another similar to 2 Myrs for the magma ocean to freeze at the surface. The cooling rate was determined by atmospheric thermal blanketing. Tidal heating by the new Moon was a major energy source to the magma ocean. After the mantle solidified geothermal heat became climatologically insignificant, which allowed the steam atmosphere to condense, and left behind a similar to 100 bar, similar to 500 K CO(2) atmosphere. Thereafter cooling was governed by how quickly CO(2) was removed from the atmosphere. If subduction were efficient this could have taken as little as 10 million years. In this case the faint young Sun suggests that a lifeless Earth should have been cold and its oceans white with ice. But if carbonate subduction were inefficient the CO(2) would have mostly stayed in the atmosphere, which would have kept the surface near similar to 500 K for many tens of millions of years. Hydrous minerals are harder to subduct than carbonates and there is a good chance that the Hadean mantle was dry. Hadean heat flow was locally high enough to ensure that any ice cover would have been thin (<5 m) in places. Moreover hundreds or thousands of asteroid impacts would have been big enough to melt the ice triggering brief impact summers. We suggest that plate tectonics as it works now was inadequate to handle typical Hadean heat flows of 0.2-0.5 W/m(2). In its place we hypothesize a convecting mantle capped by a similar to 100 km deep basaltic mush that was relatively permeable to heat flow. Recycling and distillation of hydrous basalts produced granitic rocks very early, which is consistent with preserved > 4 Ga detrital zircons. If carbonates in oceanic crust subducted as quickly as they formed, Earth could have been habitable as early as 10-20 Myrs after the Moon-forming impact.

KW - hadean earth

KW - moon-forming impact

KW - origin of earth

KW - magma oceans

KW - planetary atmospheres

KW - late heavy bombardment

KW - LATE HEAVY BOMBARDMENT

KW - INNER SOLAR-SYSTEM

KW - HF-W CHRONOMETRY

KW - PRIMORDIAL TERRESTRIAL ATMOSPHERE

KW - EARLY CORE FORMATION

KW - EARTH-MOON SYSTEM

KW - FRONT FACE BASINS

KW - CONTINENTAL-CRUST

KW - ISOTOPE SYSTEMATICS

KW - DETRITAL ZIRCONS

U2 - 10.1007/s11214-007-9225-z

DO - 10.1007/s11214-007-9225-z

M3 - Article

SN - 0038-6308

VL - 129

SP - 35

EP - 78

JO - Space Science Reviews

JF - Space Science Reviews

IS - 1-3

T2 - Workshop on Geology and Habitability of Terrestrial Planets

Y2 - 5 September 2005 through 9 September 2005

ER -

Emergence of a habitable planet

Abstract

Keywords / Materials (for Non-textual outputs)

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