NASA: Global Warming to Make Summers in Eastern U.S. Hotter
Greenhouse-gas warming may raise average summer temperatures in the eastern United States nearly 10 degrees Fahrenheit by the 2080s, according to a new study announced on May 9 by National Aeronautics and Space Administration (NASA) scientists.
"There is the potential for extremely hot summertime temperatures in the future, especially during summers with less-than-average frequent rainfall," said lead author Barry Lynn of NASA's Goddard Institute for Space Studies and Columbia University, New York.
The research found that eastern U.S. summer daily high temperatures that currently average in the low-to-mid-80s (degrees Fahrenheit) will most likely soar into the low-to-mid-90s during typical summers by the 2080s. In extreme seasons -- when precipitation falls infrequently -- July and August daily high temperatures could average between 100 degrees Fahrenheit and 110 degrees Fahrenheit in cities such as Chicago, Washington and Atlanta.
To reach their conclusions, the researchers analyzed nearly 30 years of observational temperature and precipitation data and also used computer model simulations that considered soil, atmospheric, and oceanic conditions and projected changes in greenhouse gases. The simulations were produced using a widely used weather prediction model coupled to a global model developed by NASA's Goddard Institute for Space Studies.
The global model, one of the models used in the recently issued climate report by the Intergovernmental Panel on Climate Change (IPCC), was used in this study to identify future changes in large-scale atmospheric circulation patterns due to the build up of greenhouse gases. This information was then fed into the weather prediction model to forecast summer-to-summer temperature variability in the eastern United States during the 2080s.
The weather model showed that extreme summertime surface temperatures developed when carbon dioxide emissions were assumed to continue to increase about two percent a year, the "business as usual" scenario. These findings are too recent to be included in the latest IPCC report.
The weather prediction model used in this research is advantageous because it assesses details about future climate at a smaller geographic scale than global models, providing reliable simulations not only on the amounts of summer precipitation, but also on its frequency and timing. This is an important capability for predicting summer temperatures because observed daily temperatures are usually higher on rainless days and when precipitation falls less frequently than normal, the researchers said.
Observational climate data also showed that sea surface temperatures in the Pacific Ocean have a significant influence on summer air temperatures in the eastern United States.
"Relatively cool waters in the eastern Pacific often result in stubborn summer high-pressure systems over the eastern states that block storms, reducing the frequency of precipitation below normal,? noted study co-author Richard Healy of the Woods Hole Oceanographic Institution, Woods Hole, Mass. "Less frequent storms result in higher surface and atmospheric temperatures that then feedback on the atmospheric circulation to further reduce storm frequency and raise surface temperatures even more."
The global model simulated rainfall too frequently, so that its surface temperatures were not appropriately sensitive to interannual changes in Pacific sea surface temperatures. "Since the weather prediction model simulated the frequency and timing of summer precipitation more reliably than the global model, its daily high temperature predictions for the future are also believed to be more accurate,? added co-author Leonard Druyan, NASA Goddard Institute for Space Studies and Columbia University.
In comparison, the researchers say that a number of the global models used in previous studies of future climate change predict too frequent precipitation that often falls too early in the day. As a result, they tend to underestimate the amount of future warming by reflecting solar radiation back to space before it can warm the surface and by simulating excessive evaporation from the wet ground.
To the authors' knowledge, this is the first study that has documented the impact of precipitation simulation imperfections on model predictions of surface air temperature. "Using high-resolution weather prediction models, we were able to show how greenhouse gases enhance feedbacks between precipitation, radiation and atmospheric circulations that will likely lead to extreme temperatures in our not so distant future," Lynn said.
For more information, contact NASA's Goddard Space Flight Center at http://www.nasa.gov/centers/goddard/home/index.html.
This article originally appeared in the 05/01/2007 issue of Environmental Protection.