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United States Department of Agriculture

Agricultural Research Service

Research Project: MANAGEMENT TECHNOLOGIES FOR ARID RANGELANDS Title: Plant-soil feedbacks and the reversal of desertification with climate change

Authors
item Peters, Debra
item Yao, Jin -
item Anderson, John -
item Sala, Osvaldo -

Submitted to: International Rangeland Congress
Publication Type: Proceedings
Publication Acceptance Date: February 17, 2011
Publication Date: April 2, 2011
Citation: Peters, D.C., Yao, J., Anderson, J., Sala, O.E. 2011. Plant-soil feedbacks and the reversal of desertification with climate change. Proceedings of the IX International Rangeland Congress, April 2-8, 2011, Rosario, Argentina. p. 292-296.

Technical Abstract: Our objective was to provide a conceptual framework for perennial grass recovery in a series of wet years, which includes both plant-soil feedbacks that increase available water to grasses and effects of precipitation on a sequence of recovery-related processes. We tested hypotheses based on this framework for grasslands and shrublands in the Chihuahuan Desert, the largest desert in North America. Results show that a sequence of 5 wet years following 14 years of variable rainfall increased production in resource conserving ecosystem types greater than predicted based on rainfall alone. The increase in production was primarily by herbaceous plants, which captured water locally to increase plant available water to both existing plants and new recruits. The sequence of wet years allowed a series of linked plant processes to occur that resulted in the establishment and survival of perennial grasses and forbs. We predict that a continued series of wet years will maintain the herbaceous component of these systems, and may act to reverse desertification on degraded shrublands, and to maintain perennial grasslands without management inputs. Degraded shrublands located on slopes susceptible to runoff of water responded linearly to annual precipitation in multiple wet years, and are expected to be resistant to a shift back towards grasslands under a directional increase in precipitation.

Last Modified: 10/25/2014