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AGU: Journal of Geophysical Research, Atmospheres

 

Keywords

  • ENSO
  • Russian heat wave
  • climate change
  • climate extremes
  • sea surface temperatures
  • teleconnections

Index Terms

  • 1610 - Atmosphere
  • 1620 - Climate dynamics
  • 1637 - Regional climate change
  • 3305 - Climate change and variability
  • 3319 - General circulation

Paper in Press

JOURNAL OF GEOPHYSICAL RESEARCH, doi:10.1029/2012JD018020

Climate extremes and climate change: The Russian Heat Wave and other Climate Extremes of 2010

Key Points
  • Climate extremes in 2010 relate to high sea surface temperatures
  • The Russian heat wave has a climate change component
  • A global perspective is essential

Authors:

Kevin E Trenberth

John Fasullo

A global perspective is developed on a number of high impact climate extremes in 2010 through diagnostic studies of the anomalies, diabatic heating, and global energy and water cycles that demonstrate relationships among variables and across events. Natural variability, especially ENSO, and global warming from human influences together resulted in very high sea surface temperatures (SSTs) in several places that played a vital role in subsequent developments. Record high SSTs in the Northern Indian Ocean in May 2010, the Gulf of Mexico in August 2010, the Caribbean in September 2010, and north of Australia in December 2010 provided a source of unusually abundant atmospheric moisture for nearby monsoon rains and flooding in Pakistan, Colombia, and Queensland. The resulting anomalous diabatic heating in the northern Indian and tropical Atlantic Oceans altered the atmospheric circulation by forcing quasi-stationary Rossby waves and altering monsoons. The anomalous monsoonal circulations had direct links to higher latitudes: from Southeast Asia to southern Russia, and from Colombia to Brazil. Strong convection in the tropical Atlantic in northern summer 2010 was associated with a Rossby wavetrain that extended into Europe creating anomalous cyclonic conditions over the Mediterranean area while normal anticyclonic conditions shifted downstream where they likely interacted with an anomalously strong monsoon circulation, helping to support the persistent atmospheric anticyclonic regime. This set the stage for the "blocking" anticyclone and associated Russian heat wave and wild fires. Attribution is limited by shortcomings in models in replicating monsoons, teleconnections and blocking.

Received 27 April 2012; accepted 25 July 2012.

Citation: Trenberth, K. E. and J. Fasullo (2012), Climate extremes and climate change: The Russian Heat Wave and other Climate Extremes of 2010, J. Geophys. Res., doi:10.1029/2012JD018020, in press.