Anders Levermann: Global warming increases the risk of abrupt monsoon transitions from high-precipitation to dry periods

Monsoon model indicates potential for abrupt transitions

ScienceDaily, October 16, 2009 — A self-amplifying effect presently sustains monsoon winds, but it could also disrupt the circulation over land and sea. The periodical rainfall could stop from one season to another or for months within seasons. High air pollution could lead to the disruption, researchers of the Potsdam Institute for Climate Impact Research report in the Proceedings of the National Academy of Sciences, Online Early Edition. Global warming increases the risk of abrupt monsoon transitions from high-precipitation to dry periods.

"The agricultural food supply for around two billion people in Asia and Africa depends on the eponymous regularity of monsoon rainfall," says the lead author Anders Levermann. The name "monsoon" stems from the Arabic word "mausim" for "season." However, months with extremely scarce precipitation have been observed within monsoon seasons, as in India in 2002, causing economic and humanitarian problems in the affected regions. During the past 11,000 years rainfall in monsoon regions has undergone strong and abrupt changes repeatedly.

The researchers investigated how such irregularities or disruptions of monsoon circulations can come about. "Our analysis shows on the basis of observations that there could be two stable states for monsoon systems and the possibility of abrupt transitions from one to the other," says Levermann.

The driving force of monsoon systems depends on different air temperatures. In spring, the air over land is warmed up more rapidly than the air over the sea. The warmer air rises and moist and cooler air from the ocean flows landwards and yields precipitation, which has two effects: the rainfall cools the land surface, but also releases latent heat, when water vapour condenses to raindrops. The more moist air is transported landwards, the more latent heat is released through rainfall and the more moist air is drawn towards land. This self amplification, named moisture-advection feedback, sustains the temperature difference and the entire circulation. However, the self-amplification is vulnerable and may lead to abrupt changes in response to relatively weak external perturbations, the authors state.

The PIK researchers now present a conceptual model that captures the self-amplification feedback. The basic equations show that there is a critical value of irradiation from the sun for a monsoon circulation to start. If irradiation falls below the critical value, for instance due to high air pollution, no conventional monsoon can develop. Above the critical value, one state with and one state without a monsoon circulation exist.

This allows for an abrupt transition to occur in one of two different ways. First, climatic shifts can push the system across the critical threshold. The transition would occur from one season to the other and last as long as the climatic shift prevails. The second possibility is abrupt transitions between the two stable states, when the system is -- as current monsoon circulations are -- in the bi-stable regime above the critical threshold. Within one rainy season weakening of monsoon winds and latent heat release could decrease the temperature difference between land and sea until the circulation is disrupted.

Using the model and observational data from the past 60 years the researchers computed the critical values for monsoon systems in India, China, Bangladesh, West Africa, North America and Australia. "We are working on more precise assessments of the vulnerabilities of monsoon systems," says co-author Jacob Schewe. Currently, large uncertainties still exist. While global warming would increase precipitation, aerosol emissions, especially in countries like India and China, could reduce monsoon stability. "Oscillations between months with strong and months with extremely weak rainfall could overstrain the people's capacity to adapt," says Schewe. Thus, the researchers want to further investigate the risks for abrupt monsoon transitions in the respective regions. The article "Basic mechanism for abrupt monsoon transitions" will appear in print in a Special Feature of the Proceedings of the National Academy of Sciences. The Special Feature contains analyses of eight potential tipping elements in the Earth System and is edited by Hans Joachim Schellnhuber, director of PIK.

Adapted from materials provided by Potsdam Institute for Climate Impact Research (PIK).

Link to article:  http://www.sciencedaily.com/releases/2009/10/091029152301.htm

A. Levermann et al., PNAS, 2009, Basic mechanism for abrupt monsoon transitions

Proceedings of the National Academy of Sciences, published online before print October 26, 2009; doi: 10.1073/pnas.0901414106

Basic mechanism for abrupt monsoon transitions

Anders Levermann*, Jacob Schewe, Vladimir Petoukhov, and Hermann Held

Edited by Hans Joachim Schellnhuber, Potsdam Institute for Climate Impact Research, Potsdam, Germany and approved August 18, 2009 (received for review February 11, 2009.

Abstract

Monsoon systems influence the livelihood of hundreds of millions of people. During the Holocene and last glacial period, rainfall in India and China has undergone strong and abrupt changes. Though details of monsoon circulations are complicated, observations reveal a defining moisture-advection feedback that dominates the seasonal heat balance and might act as an internal amplifier, leading to abrupt changes in response to relatively weak external perturbations. Here we present a minimal conceptual model capturing this positive feedback. The basic equations, motivated by observed relations, yield a threshold behavior, robust with respect to addition of other physical processes. Below this threshold in net radiative influx, R_c, no conventional monsoon can develop; above R_c, two stable regimes exist. We identify a nondimensional parameter l that defines the threshold and makes monsoon systems comparable with respect to the character of their abrupt transition. This dynamic similitude may be helpful in understanding past and future variations in monsoon circulation. Within the restrictions of the model, we compute R_c for current monsoon systems in India, China, the Bay of Bengal, West Africa, North America, and Australia, where moisture advection is the main driver of the circulation.

*Correspondence e-mail: anders.levermann@pik-potsdam.de

Link to abstract:  http://www.pnas.org/content/early/2009/10/23/0901414106.abstract

Nerilie J. Abram et al., Recent intensification of tropical climate variability in the Indian Ocean

Letter abstract

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Nature Geoscience 1, 849–853 (2008)
Published online: 16 November 2008 | doi:10.1038/ngeo357

Recent intensification of tropical climate variability in the Indian Ocean

Nerilie J. Abram^1,2, Michael K. Gagan¹, Julia E. Cole³, Wahyoe S. Hantoro⁴ and Manfred Mudelsee⁵

The interplay of the El Niño Southern Oscillation, Asian monsoon and Indian Ocean Dipole (IOD)^{1, 2, 3} drives climatic extremes in and around the Indian Ocean. Historical^{4, 5} and proxy^{6, 7, 8, 9} records reveal changes in the behaviour of the El Niño Southern Oscillation and the Asian monsoon over recent decades^{10, 11, 12}. However, reliable instrumental records of the IOD cover only the past 50 years^{1, 3}, and there is no consensus on long-term variability of the IOD or its possible response to greenhouse gas forcing¹³. Here we use a suite of coral oxygen-isotope records to reconstruct a basin-wide index of IOD behaviour since AD 1846. Our record reveals an increase in the frequency and strength of IOD events during the twentieth century, which is associated with enhanced seasonal upwelling in the eastern Indian Ocean. Although the El Niño Southern Oscillation has historically influenced the variability of both the IOD and the Asian monsoon^{3, 8, 10}, we find that the recent intensification of the IOD coincides with the development of direct, positive IOD–monsoon feedbacks. We suggest that projected greenhouse warming may lead to a redistribution of rainfall across the Indian Ocean and a growing interdependence between the IOD and Asian monsoon precipitation variability.

1. Research School of Earth Sciences, The Australian National University, Canberra, ACT 0200, Australia
2. British Antarctic Survey, Natural Environment Research Council, Cambridge CB3 0ET, UK
3. Department of Geosciences, University of Arizona, Tucson, AZ 85721, USA
4. Research and Development Center for Geotechnology, Indonesian Institute of Sciences (LIPI), Bandung 40135, Indonesia
5. Climate Risk Analysis, Schneiderberg 26, 30167 Hanover, Germany

Correspondence to: Nerilie J. Abram^1,2 e-mail: nabr@bas.ac.uk

Correspondence to: Michael K. Gagan¹ e-mail: Michael.Gagan@anu.edu.au

Link to abstract: http://www.nature.com/ngeo/journal/v1/n12/abs/ngeo357.html