Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox

Research output: Contribution to conferenceConference abstract for conferenceResearchpeer-review

Standard

Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox. / Rosing, Minik Thorleif; Brid, Dennis K.; Sleep, Norman H.; Bjerrum, Christian J.

2010. Abstract from EGU General Assembly 2010, Vienna, Austria.

Research output: Contribution to conferenceConference abstract for conferenceResearchpeer-review

Harvard

Rosing, MT, Brid, DK, Sleep, NH & Bjerrum, CJ 2010, 'Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox', EGU General Assembly 2010, Vienna, Austria, 02/05/2010 - 07/05/2010. <http://meetingorganizer.copernicus.org/EGU2010/EGU2010-15268.pdf>

APA

Rosing, M. T., Brid, D. K., Sleep, N. H., & Bjerrum, C. J. (2010). Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox. Abstract from EGU General Assembly 2010, Vienna, Austria. http://meetingorganizer.copernicus.org/EGU2010/EGU2010-15268.pdf

Vancouver

Rosing MT, Brid DK, Sleep NH, Bjerrum CJ. Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox. 2010. Abstract from EGU General Assembly 2010, Vienna, Austria.

Author

Rosing, Minik Thorleif ; Brid, Dennis K. ; Sleep, Norman H. ; Bjerrum, Christian J. / Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox. Abstract from EGU General Assembly 2010, Vienna, Austria.1 p.

Bibtex

@conference{528295a84a204e6195aa9441234c9aaa,
title = "Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox",
abstract = "There is ample geological evidence that Earth{\textquoteright}s climate resembled the present during the Archaean, despite a much lower solar luminosity. This was cast as a paradox by Sagan and Mullen in 1972. Several solutions to the paradox have been suggested, mostly focusing on adjustments of the radiative properties of Earth{\textquoteright}s atmosphere e.g. Kasting (1993), by increasing the mixing ratio of CO2 and/or adding various other greenhouse gasses. We have used banded iron formation (BIF), which are chemical sediments precipitated out of the Archaean ocean to characterize the composition of the atmosphere. The stability relations of magnetite, which is ubiquitous in Archaean BIFs, preclude CO2 mixing ratios much higher than the present atmospheric level. Likewise, magnetite stability is consistent with atmospheric H2 controlled at the lower limit for H2 metabolism by methanogenic phototrophic organisms.In the absence of substantial compensation for the lower solar irradiance by greenhouse gasses in the atmosphere, we have examined the factors that controlled Earth{\textquoteright}s albedo. These are primarily the surface albedo of Earth andthe abundance and properties of clouds. We have applied a model that takes into account the apparent growth of Earth continents (Collerson and Kamber 1999) and the absence of land vegetation during the Precambrian for the evolution of the surface albedo, and a model for the abundance and properties of clouds that takes into account the lower abundance of biogenic cloud condensation nuclei in a less productive prokaryotic world. The higher transparency of the atmosphere for short wave incoming solar radiation and the lower surface albedo on an earlyEarth dominated by oceans, provided sufficient compensation for the lower solar irradiance to allow the presence of liquid oceans, even at greenhouse gas concentrations broadly similar to the present day values. We therefore suggest that the thermostasis during Earth geologic record, is not paradoxical, but is the combined effect of many factors, which are to a large part biologically controlled.",
author = "Rosing, {Minik Thorleif} and Brid, {Dennis K.} and Sleep, {Norman H.} and Bjerrum, {Christian J.}",
year = "2010",
month = may,
day = "2",
language = "English",
note = "null ; Conference date: 02-05-2010 Through 07-05-2010",

}

RIS

TY - ABST

T1 - Geochemical and biologic constraints on the Archaean atmosphere and climate – A possible solution to the faint early Sun paradox

AU - Rosing, Minik Thorleif

AU - Brid, Dennis K.

AU - Sleep, Norman H.

AU - Bjerrum, Christian J.

PY - 2010/5/2

Y1 - 2010/5/2

N2 - There is ample geological evidence that Earth’s climate resembled the present during the Archaean, despite a much lower solar luminosity. This was cast as a paradox by Sagan and Mullen in 1972. Several solutions to the paradox have been suggested, mostly focusing on adjustments of the radiative properties of Earth’s atmosphere e.g. Kasting (1993), by increasing the mixing ratio of CO2 and/or adding various other greenhouse gasses. We have used banded iron formation (BIF), which are chemical sediments precipitated out of the Archaean ocean to characterize the composition of the atmosphere. The stability relations of magnetite, which is ubiquitous in Archaean BIFs, preclude CO2 mixing ratios much higher than the present atmospheric level. Likewise, magnetite stability is consistent with atmospheric H2 controlled at the lower limit for H2 metabolism by methanogenic phototrophic organisms.In the absence of substantial compensation for the lower solar irradiance by greenhouse gasses in the atmosphere, we have examined the factors that controlled Earth’s albedo. These are primarily the surface albedo of Earth andthe abundance and properties of clouds. We have applied a model that takes into account the apparent growth of Earth continents (Collerson and Kamber 1999) and the absence of land vegetation during the Precambrian for the evolution of the surface albedo, and a model for the abundance and properties of clouds that takes into account the lower abundance of biogenic cloud condensation nuclei in a less productive prokaryotic world. The higher transparency of the atmosphere for short wave incoming solar radiation and the lower surface albedo on an earlyEarth dominated by oceans, provided sufficient compensation for the lower solar irradiance to allow the presence of liquid oceans, even at greenhouse gas concentrations broadly similar to the present day values. We therefore suggest that the thermostasis during Earth geologic record, is not paradoxical, but is the combined effect of many factors, which are to a large part biologically controlled.

AB - There is ample geological evidence that Earth’s climate resembled the present during the Archaean, despite a much lower solar luminosity. This was cast as a paradox by Sagan and Mullen in 1972. Several solutions to the paradox have been suggested, mostly focusing on adjustments of the radiative properties of Earth’s atmosphere e.g. Kasting (1993), by increasing the mixing ratio of CO2 and/or adding various other greenhouse gasses. We have used banded iron formation (BIF), which are chemical sediments precipitated out of the Archaean ocean to characterize the composition of the atmosphere. The stability relations of magnetite, which is ubiquitous in Archaean BIFs, preclude CO2 mixing ratios much higher than the present atmospheric level. Likewise, magnetite stability is consistent with atmospheric H2 controlled at the lower limit for H2 metabolism by methanogenic phototrophic organisms.In the absence of substantial compensation for the lower solar irradiance by greenhouse gasses in the atmosphere, we have examined the factors that controlled Earth’s albedo. These are primarily the surface albedo of Earth andthe abundance and properties of clouds. We have applied a model that takes into account the apparent growth of Earth continents (Collerson and Kamber 1999) and the absence of land vegetation during the Precambrian for the evolution of the surface albedo, and a model for the abundance and properties of clouds that takes into account the lower abundance of biogenic cloud condensation nuclei in a less productive prokaryotic world. The higher transparency of the atmosphere for short wave incoming solar radiation and the lower surface albedo on an earlyEarth dominated by oceans, provided sufficient compensation for the lower solar irradiance to allow the presence of liquid oceans, even at greenhouse gas concentrations broadly similar to the present day values. We therefore suggest that the thermostasis during Earth geologic record, is not paradoxical, but is the combined effect of many factors, which are to a large part biologically controlled.

M3 - Conference abstract for conference

Y2 - 2 May 2010 through 7 May 2010

ER -

ID: 32444585