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K. Karlstrom, S. Harlan, M. Williams, J. McLelland, J. Geissman (1999)
Refining Rodinia: geologic evidence for the Australia-western U
(1998)
From daisyworld to GCMs: using models to understand the regulation
RA Berner, AC Lasaga, RM Garrels (1983)
The carbonate-silicate geochemical cycle and its effect on atmospheric carbon dioxide and climateAm J Sci, 283
L. Kump (1988)
Terrestrial feedback in atmospheric oxygen regulation by fire and phosphorusNature, 335
T. Lenton, A. Watson (2000)
Redfield revisited: 2. What regulates the oxygen content of the atmosphere?Global Biogeochemical Cycles, 14
R. Garrels, A. Lerman, F. Mackenzie (1976)
Controls of atmospheric O2 and CO2: past, present, and futureAmerican Scientist, 64
R. Saltus, T. Hudson, G. Connard (1999)
A new magnetic view of AlaskaGsa Today, 9
FT Mackenzie, LM Ver, A Lerman (1998)
Asian change in the context of global change
R. Berner, A. Lasaga, R. Garrels (1983)
The carbonate-silicate geochemical cycle and its effect on atmospheric carbon dioxide over the past 100 million yearsAmerican Journal of Science, 283
F. Mackenzie (1995)
Our Changing Planet: An Introduction to Earth System Science and Global Environmental Change
B. Saltzman, R. Moritz (1980)
A time‐dependent climatic feedback system involving sea‐ice extent, ocean temperature, and CO2Tellus A, 32
(1998)
From daisyworld to GCMs : using models to understand the regulation of climate
James Walker, P. Hays, J. Kasting (1981)
A negative feedback mechanism for the long‐term stabilization of Earth's surface temperatureJournal of Geophysical Research, 86
L. François, Vincent Lefebvre, Y. Goddéris, G. Munhoven, Alexandra‐Jane Henrot (2006)
Atmospheric Carbon Dioxide and Climate Over Phanerozoic Times, 2006
R. Berner, D. Beerling, R. Dudley, J. Robinson, R. Wildman (2003)
PHANEROZOIC ATMOSPHERIC OXYGENAnnual Review of Earth and Planetary Sciences, 31
R. Garrels, A. Lerman, F. Mackenzie (1976)
Controls of Atmospheric O_2 and and CO_2 : Past, Present, and Future, 64
(1998)
Coupled biogeochemical cycles of carbon , nitrogen , phosphorus , and sulfur in the land - ocean - atmosphere system
(1991)
A first - order model of late Cenozoic climate change
Noam Bergman, T. Lenton, A. Watson (2004)
COPSE: a new model of biogeochemical cycling over Phanerozoic timeAmerican Journal of Science, 304
R. Berner (1999)
A New Look at the Long-term Carbon Cycle
Lenton Tim, RA Betts (1998)
ERCA—Volume 3—from urban air pollution to extra-solar planets
B. Saltzman, K. Maasch (1991)
A first-order global model of late Cenozoic climatic change II. Further analysis based on a simplification of CO2 dynamicsClimate Dynamics, 5
A complex cause–effect type earth systems diagram is presented that represents the interrelation of the global carbon and phosphorus cycles over geological time. It demonstrates how a lot of information can be represented in an extremely compact manner and how relatively unrecognized positive and negative feedbacks are revealed by tracing paths on the diagram. Emphasis is on how the C and P cycles affect the levels of atmospheric CO2 and O2, often via rather indirect paths.
Aquatic Geochemistry – Springer Journals
Published: Jul 24, 2013
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