Effect of seawater carbonate concentration on foraminiferal carbon and oxygen isotopes

Stable oxygen and carbon isotope measurements on biogenic calcite and aragonite have become standard tools for reconstructing past oceanographic and climatic change. In aquatic organisms, 18O/16O ratios in the shell carbonate are a function of the ratio in the sea water and the calcification temperature. In contrast, 13C/12C ratios are controlled by the ratio of dissolved inorganic carbon in sea water and physiological processes such as respiration and symbiont photosynthesis. These geochemical proxies have been used with analyses of foraminifera shells to reconstruct global ice volumes, surface and deep ocean temperatures,, ocean circulation changes and glacial–interglacial exchange between the terrestrial and oceanic carbon pools. Here, we report experimental measurements on living symbiotic and non-symbiotic plankton foraminifera (Orbulina universa and Globigerina bulloides respectively) showing that the 13C/12C and 18O/16O ratios of the calcite shells decrease with increasing seawater [CO32−]. Because glacial-period oceans had higher pH and [CO32−] than today, these new relationships confound the standard interpretation of glacial foraminiferal stable-isotope data. In particular, the hypothesis that the glacial–interglacial shift in the 13C/12C ratio was due to a transfer of terrestrial carbon into the ocean can be explained alternatively by an increase in ocean alkalinity. A carbonate-concentration effect could also help explain some of the extreme stable-isotope variations during the Proterozoic and Phanerozoic aeons.

[1]  I. Lerche,et al.  Opening the carbon isotope "vital effect" black box, 2, Quantitative model for interpreting foramini , 1991 .

[2]  A. J. Kaufman,et al.  The Vendian record of Sr and C isotopic variations in seawater: Implications for tectonics and paleoclimate , 1993 .

[3]  N. J. Shackleton,et al.  Carbon isotope data in core V19-30 confirm reduced carbon dioxide concentration in the ice age atmosphere , 1983, Nature.

[4]  Laurent Labeyrie,et al.  Deepwater source variations during the last climatic cycle and their impact on the global deepwater circulation , 1988 .

[5]  D. Wilbur,et al.  CARBON ISOTOPE FRACTIONATION DURING GAS-WATER EXCHANGE AND DISSOLUTION OF CO2 , 1995 .

[6]  T. McConnaughey 13C and 18O isotopic disequilibrium in biological carbonates: I. Patterns , 1989 .

[7]  C. Paull,et al.  CARBON ISOTOPES IN BIOLOGICAL CARBONATES : RESPIRATION AND PHOTOSYNTHESIS , 1997 .

[8]  J. Kasting,et al.  New Constraints on Precambrian Ocean Composition , 1993, The Journal of Geology.

[9]  W. Broecker Oxygen Isotope Constraints on Surface Ocean Temperatures , 1986, Quaternary Research.

[10]  H. Spero Do planktic foraminifera accurately record shifts in the carbon isotopic composition of seawater ΣCO2 , 1992 .

[11]  E. Padan,et al.  Mechanisms for the uptake of inorganic carbon by two species of symbiont-bearing foraminifera , 1989 .

[12]  A. Mix,et al.  Carbon isotope records from pacific surface waters and atmospheric carbon dioxide , 1992 .

[13]  H. Schwarcz,et al.  Rapid climate change in the North Atlantic during the Younger Dryas recorded by deep-sea corals , 1997, Nature.

[14]  P. Wiebe,et al.  Vertical distribution and isotopic fractionation of living planktonic foraminifera from the Panama Basin , 1982, Nature.

[15]  J. Hoefs,et al.  Oxygen isotope exchange between carbonic acid, bicarbonate, carbonate, and water: A re-examination of the data of McCrea (1950) and an expression for the overall partitioning of oxygen isotopes between the carbonate species and water , 1993 .

[16]  T. McConnaughey 13C and 18O isotopic disequilibrium in biological carbonates: II. In vitro simulation of kinetic isotope effects , 1989 .

[17]  E. Mosley‐Thompson,et al.  Late Glacial Stage and Holocene Tropical Ice Core Records from Huascar�n, Peru , 1995, Science.

[18]  W. Broecker,et al.  Evidence for a higher pH in the glacial ocean from boron isotopes in foraminifera , 1995, Nature.

[19]  Nicholas J Shackleton,et al.  Oxygen Isotope and Palaeomagnetic Stratigraphy of Equatorial Pacific Core V28-238: Oxygen Isotope Temperatures and Ice Volumes on a 105 Year and 106 Year Scale , 1973, Quaternary Research.

[20]  C. Lorius,et al.  Vostok ice core provides 160,000-year record of atmospheric CO2 , 1987, Nature.

[21]  J. Veizer,et al.  sup 18 O/ sup 16 O and sup 13 C/ sup 12 C in lower Paleozoic articulate brachiopods: Implications for the isotopic composition of seawater , 1992 .

[22]  R. Berner Geocarb III: A Revised Model of Atmospheric CO2 over Phanerozoic Time , 1994 .

[23]  W. Broecker,et al.  What Caused the Glacial to Interglacial CO2 Change , 1993 .

[24]  J. Duplessy,et al.  Variations in mode of formation and temperature of oceanic deep waters over the past 125,000 years , 1987, Nature.

[25]  D. Lea,et al.  Experimental determination of stable isotope variability in Globigerina bulloides: implications for paleoceanographic reconstructions , 1996 .

[26]  Richard G. Fairbanks,et al.  Tropical Temperature Variations Since 20,000 Years Ago: Modulating Interhemispheric Climate Change , 1994, Science.

[27]  D. Lea,et al.  Intraspecific stable isotope variability in the planktic foraminiferaGlobigerinoides sacculifer: Results from laboratory experiments , 1993 .

[28]  N. Shackleton Carbon-13 in Uvigerina: Tropical Rainforest History and the Equatorial Pacific Carbonate Dissolution Cycles , 1977 .

[29]  Steven L. Parker,et al.  Photosynthesis in the symbiotic planktonic foraminifer Orbulina universa, and its potential contribution to oceanic primary productivity , 1985 .

[30]  J. McCrea On the Isotopic Chemistry of Carbonates and a Paleotemperature Scale , 1950 .

[31]  Samuel Epstein,et al.  REVISED CARBONATE-WATER ISOTOPIC TEMPERATURE SCALE , 1953 .

[32]  T. Crowley Ice Age terrestrial carbon changes revisited , 1995 .