El Nino and its partner La Nina, the warm and cold phases in the eastern half of the tropical Pacific, play havoc with climate worldwide. Predicting El Nino events more than several months ahead is now routine, but predicting how it will change in a warming world has been hampered by the short instrumental record.

An international team of climate scientists from the University of Hawai‘i at Manoa recently found that annually resolved tree-ring records from North America, particularly from the U. S. Southwest, give a continuous representation of the intensity of El Nino events over the past 1,100 years and can be used to improve El Nino predictions. The study, spearheaded by postdoctoral fellow Jinbao Li and co-authored by meteorology professor Shang-Ping Xie of the International Pacific Research Center, was published in the May 6 issue of Nature Climate Change.

Tree rings in the U. S. Southwest, the team found, agree well with the 150-year instrumental sea surface temperature records in the tropical Pacific. During El Nino, the unusually warm surface temperatures in the eastern Pacific lead to changes in the atmospheric circulation, causing unusually wetter winters in the U. S. Southwest, and thus wider tree rings; unusually cold eastern Pacific temperatures during La Nina lead to drought and narrower rings. The tree-ring records, furthermore, match well existing reconstructions of the El Nino-Southern Oscillation and correlate highly, for instance, with d18O isotope concentrations of both living corals and corals that lived hundreds of years ago around Palmyra in the central Pacific.

“Our work revealed that the towering trees on the mountain slopes of the U. S. Southwest and the colorful corals in the tropical Pacific both listen to the music of El Nino, which shows its signature in their yearly growth rings,” explained Li. “The coral records, however, are brief, whereas the tree-ring records from North America supply us with a continuous El Nino record reaching back 1,100 years.”

The tree rings reveal that the intensity of El Nino has been highly variable, with decades of strong El Nino events and decades of little activity. The weakest El Nino activity happened during the Medieval Climate Anomaly in the 11th century, whereas the strongest activity has been since the 18th century.

These different periods of El Nino activity are related to long-term changes in Pacific climate. Cores taken from lake sediments in the Galapagos, northern Yucatan, and the Pacific Northwest reveal that the eastern–central tropical Pacific climate swings between warm and cool phases, each lasting from 50 to 90 years. During warm phases, El Nino and La Nina events were more intense than usual. During cool phases, they deviated little from the long-term average as, for instance, during the Medieval Climate Anomaly when the eastern tropical Pacific was cool.

“Since El Nino causes climate extremes around the world, it is important to know how it will change with global warming,” says Xie. “Current models diverge in their projections of its future behavior, with some showing an increase in amplitude, some no change, and some even a decrease. Our tree-ring data offer key observational benchmarks for evaluating and perfecting climate models and their predictions of the El Nino-Southern Oscillation under global warming.”

This research was funded by the National Science Foundation, National Oceanic and Atmospheric Administration, Japan Agency for Marine-Earth Science and Technology, National Basic Research Program of China, and the National Natural Science Foundation of China.

Contact: External Affairs & University Relations, Tel: (808)956-8109, Email: ur@hawaii. edu

Source: University of Hawai?i at Manoa

Eco Info
Powered by Joomla CMS.