Archer Reprint Server

University of Chicago Department of the Geophysical Sciences

Review Papers

What caused the glacial / interglacial pCO2 cycles? Archer, D., A. Winguth, D. Lea, and N. Mahowald. Reviews of Geophysics 38: 159-189, 2000.
Modeling CO2 in the ocean: A review D. Archer, in Scaling of Trace Gas Fluxes between Terrestrial and Aquatic Ecosystems and the Atmosphere, edited by A.F. Bouwman, Elsevier, in press.
Upper Ocean Physics as Relevant to Ecosystem Dynamics: a Tutorial. D. Archer, Ecosystem Applications, 5(3): 724-739, 1995

Ocean control of the pCO2 of the Atmosphere

What caused the glacial / interglacial pCO2 cycles? Archer, D., A. Winguth, D. Lea, and N. Mahowald. Reviews of Geophysics 38: 159-189, 2000.
Atmospheric CO2 sensitivity to the biological pump in the ocean D. Archer, G. Eshel, A. Winguth, and W. Broecker. Global Biogeochemical Cycles 14: 1219-1230, 2000.
Effect of deep-sea sedimentary calcite preservation on atmospheric CO2 concentration, D. Archer and E. Maier-Reimer, Nature, 367: 260-264, 1994

Fate of Fossil Fuel CO2

Dynamics of fossil fuel neutralization by Marine CaCO3, Archer, D., Kheshgi, H., and Maier-Reimer, E., Global Biogeochemical Cycles 12: 259-276, 1998
Multiple timescales for neutralization of fossil fuel CO₂, Archer, D., Kheshgi, H., and Maier-Reimer, E., Geophysical Research Letters 24(4): 405-408, 1997

Effect of Fossil Fuel CO2 on Coral Reefs

Geochemical consequences of increased atmospheric CO2 on coral reefs. Kleypas, J., R.W. Buddemeier, D. Archer, J.-P. Gattuso, C. Langdon, and B. Opdyke, Science 284: 118-120, 1999.

Sediment Geochemistry

A model of suboxic sedimentary diagenesis suitable for automatic tuning and gridded global domains. D. Archer, J.L. Morford, and S. Emerson, submitted to Global Biogeochemical Cycles. (Run the model on-line)
A data-driven model of the calcite lysocline. Archer, Global Biogeochemical Cycles 10: 511-526, 1996.
An atlas of the distribution of calcium carbonate in sediments of the deep sea. D. Archer, Global Biogeochemical Cycles 10(1): 159-174, 1996.
Equatorial Pacific calcite preservation cycles: Production or dissolution?, Archer, Paleoceanography, 6, 561-572, 1991.
Modeling the Calcite Lysocline. Archer, J. Geophys Res, 96, 17,037-17,050, 1991.
What Controls Opal Preservation in Tropical Deep Sea Sediments? Paleoceanography, 8, 7-21, 1993
Derivation of the Relaxation Method Algorithm used in my CaCO3 diagenesis models (Appendix 1B from my thesis)

The Iron Cycle in the Ocean

A model of the iron cycle in the ocean D. Archer and K. Johnson, Global Biogeochemical Cycles 14: 269-279, 2000.

Last Glacial Maximum Ocean Circulation

Carbon Cycle in the Upper Ocean

The impact of fronts and mesoscale circulation on the nutrient supply and biogeochemistry of the upper ocean. Mahadevan, A., and D. Archer, J. Geophys. Res. 105: 1209-1225, 2000.
Modeling a limited region of the ocean Mahadevan, A., and D. Archer, J. Computational Physics 145: 555-574, 1998.
A timescale for dissolved organic carbon production in equatorial Pacific surface waters. D. Archer, E. Peltzer, and D. Kirchman, Global Biogeochemical Cycles 11: 435-452, 1997.
A Meeting Place of Great Ocean Currents: Shipboard Observations of a Convergent Front at 2^o N in the Pacific. D. Archer and others, Deep-Sea Res II 44: 1827-1850, 1997.
Daily, seasonal, and interannual variability of sea surface carbon and nutrient concentration in the equatorial Pacific Ocean. Archer, T. Takahashi, S. Sutherland, J. Goddard, D. Chipman, K. Rodgers, and H. Ogura, Deep-Sea Res., 43, 779-808, 1996.
Upper Ocean Physics as Relevant to Ecosystem Dynamics: a Tutorial. Archer, Ecosystem Applications, 5(3): 724-739, 1995
Numerical Hindcasting of Sea Surface pCO2 at Weathership Station Papa, Archer, Progress in Oceanography, 32, 319-351, 1993