A large body of paleoceanographic data for the Paleocene-Eocene Thermal Maximum (PETM) is based on foraminiferal stable carbon and oxygen isotope composition (delta(13)C and delta(18)O). However, the proxy records could be biased due to a "pH effect" on stable isotopes during times when the ocean became more acidic, as has been demonstrated for modern planktonic foraminifera. In this paper, we calculate the possible ranges of the pH effect on delta(13)C and delta(18)O during the PETM based on the relative pH decline (Delta pH) from the preperturbation steady state simulated by a carbon cycle model and the empirical relationships obtained from culture experiments with planktonic foraminifera. The model is configured with Eocene paleogeography and simulates Delta pH for surface, intermediate, and deep water in the major ocean basins in response to various carbon input scenarios (2000 to 5000 Pg C). For an array of scenarios, the modeled Delta pH of the surface ocean ranges from 0.1 to 0.28 units. This suggests that delta(13)C of planktonic foraminifera may be increased by up to 2.1 parts per thousand and delta(18)O may be increased by up to 0.7 parts per thousand (corresponding to over 3 degrees C error in paleotemperature estimate). Under conditions in which the model best simulates the global CaCO(3) dissolution pattern, we find marked differences in the deep-sea Delta pH between the Atlantic (-0.4) and Pacific oceans (-0.1). This would imply that the magnitude of the negative delta(13)C and delta(18)O excursions of benthic foraminifera in the Atlantic Ocean was dampened by up to 2.8 parts per thousand and 0.9 parts per thousand at maximum, respectively, relative to a constant pH scenario.

• 出版日期2010-6-23