Water isotopes during the Last Glacial Maximum: New general circulation model calculations

The application of water isotopes to estimate the glacial-interglacial cycle of temperature (T) assumes the validity of the present-day spatial relationship between T-a and delta O-18 in precipitation (delta O-18(p)) to estimate temporal changes of the temperature at a fixed location. We explored how and why the spatial relationship between annual mean T-a - delta O-18(p) is different from the temporal relationship at one location. Our general circulation-isotope model exhibits a spatial slope of 1.22 parts per thousand/degrees C between annual mean temperature at the top of the inversion layer (T-i) and d(18)O(p) over Antarctica, comparable to the observed value of 1.25 parts per thousand/degrees C from Dahe et al. (1999) and using the Phillpot and Zillman (1970) relationship between surface temperature and the temperature of the inversion layer. Over the Southern Ocean (45 degrees - 60 degrees S), local evaporation accounts for 50% of precipitation, and this evaporative flux (mean delta O-18(e) of similar to - 1%) increases the delta O-18 of vapor (mean delta O-18(v) of similar to - 16%). During the Last Glacial Maximum (LGM; 21,000 years ago), the isotopic composition of the vapor near the ice edge (similar to 60 degrees S) is calculated to be similar to the present values because evaporative recharge also accounts for similar to 50% of the precipitation over the Southern Ocean. As a result, the isotopic composition of vapor during the LGM is close to the present values at the ice edge. The apparent temporal slope over eastern Antarctica is half of the observed spatial slope. Our LGM experiment estimates an Antarctic mean annual temperature decrease of 13 degrees C at Vostok, much larger than previous estimates. Our experiments with two specifications of LGM sea surface temperatures suggest that the value of the temporal slope is related to the temperature decrease over the Southern Ocean.