Simulations of Atmospheric Variability Induced by Sea Surface Temperatures and Implications for Global Warming
- 28 October 1994
- journal article
- other
- Published by American Association for the Advancement of Science (AAAS) in Science
- Vol. 266 (5185) , 632-634
- https://doi.org/10.1126/science.266.5185.632
Abstract
An atmospheric general circulation model was forced with observed interannual changes in the global sea surface temperatures (SSTs) for the period 1982 to 1993. The simulated seasonal surface air temperature patterns over land areas closely resemble the observed. Over most of the globe, the patterns also resemble those associated with EI Niño events and are also reproduced in simulations with weak warm tropical SSTs near the date line. An exception is northern Asia, where the mechanisms for the observed warming are unclear. The results suggest that enhanced air-sea interactions resulting from recent, more persistent warm oceanic conditions in the tropics contributed to the observed global warming trend during this period.Keywords
This publication has 11 references indexed in Scilit:
- Decadal atmosphere-ocean variations in the PacificClimate Dynamics, 1994
- A Two-Tiered Approach to Long-Range Climate ForecastingScience, 1993
- Simulating the Atmospheric Response to the 1985–87 El Niño CycleJournal of Climate, 1992
- Surface Temperature Patterns Associated with the Southern OscillationJournal of Climate, 1992
- Description of the NMC Global Data Assimilation and Forecast SystemWeather and Forecasting, 1989
- A Real-Time Global Sea Surface Temperature AnalysisJournal of Climate, 1988
- Modeling the Seasonal Dependence of the Atmospheric Response to Observed El Niños in 1962–76Monthly Weather Review, 1985
- The Analysis and Display of Real Time Surface Climate DataMonthly Weather Review, 1985
- A General Circulation Model Study of January Climate Anomaly Patterns Associated with Interannual Variation of Equatorial Pacific Sea Surface TemperaturesJournal of the Atmospheric Sciences, 1983
- Seasonal Differences in the Stationary Response of a Linearized Primitive Equation Model: Prospects for Long-Range Weather Forecasting?Journal of the Atmospheric Sciences, 1980