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United States Department of Agriculture

Agricultural Research Service

Research Project: GRASSLAND PRODUCTIVITY AND CARBON DYNAMICS: CONSEQUENCES OF CHANGE IN ATMOSPHERIC CO2, PRECIPITATION, AND PLANT SPECIES COMPOSITION, ...

Location: Grassland, Soil and Water Research Laboratory

Title: Impacts of altered rainfall timing and warming in a mesic grassland ecosystem

Authors
item Blair, John -
item Fay, Philip
item Knapp, Alan -
item Smith, Melinda -
item Collins, Scott -

Submitted to: Ecological Society of America Abstracts
Publication Type: Abstract Only
Publication Acceptance Date: May 11, 2010
Publication Date: August 1, 2010
Citation: Blair, J.M., Fay, P.A., Knapp, A.K., Smith, M.D., Collins, S.L. 2010. Impacts of altered rainfall timing and warming in a mesic grassland ecosystem. In: Proceedings of the Ecological Society of America Abstracts, August 1-6, 2010, Pittsburgh, Pennsylvania. OOS 35-3.

Technical Abstract: Grasslands are highly responsive to inter- and intra-annual variability in precipitation and temperature, which interact to affect soil water dynamics and the plant and soil processes mediated by soil water availability. In the U.S. Central Plains mean temperatures are expected to increase and rainfall patterns are predicted to become more variable and extreme, with increased frequency of large rainfall events and extended inter-rainfall droughts. Changes in the timing of rainfall events will alter soil water dynamics, and increased temperatures may intensify or moderate the impacts of altered rainfall timing on key ecosystem processes, such as plant productivity, soil CO2 flux, and soil N availability. We have been assessing the consequences of these climate changes for 12 years, using field-scale rainfall manipulation plots to alter the timing of growing season rainfall events (since 1998) and infrared heaters to increase mean temperature (since 2003) in intact plots of native tallgrass prairie at the Konza Prairie Biological Station. The long-term nature of this study and inherently high inter-annual climatic variability of these grasslands allows us to begin assessing the conditions under which altered rainfall timing and warming are likely to have their largest effects. More extreme patterns of growing season rainfall, with no change in total amounts, significantly reduced the mean and increased variability in soil water content in most years. Warming increased soil temperatures by ~1.5ºC and reduced in mean soil water content. The effect of altered rainfall timing on ANPP varied across years, but when significant it reduced ANPP by 13-22%. Across all years, annual total ANPP was positively related to mean soil water content, and negatively related to within season soil moisture variability, and grasses were more responsive than forbs to soil moisture dynamics. Warming accelerated early season plant growth, but this effect did not persist through the growing season. When significant, warming reduced ANPP by 10%, with forbs generally being more responsive than grasses. Mean annual soil CO2 flux was generally reduced by altered rainfall timing by 11%, while the effects of warming were contingent on annual rainfall amounts and differed for growing and non-growing seasons. Elevated temperatures decreased growing season soil CO2 by 9% flux in dry years, but stimulated soil CO2 flux in wet years and in the non-growing season (by 11%). Altered rainfall timing increased resin-bag collected nitrate by up to two-fold, with no apparent increase in plant uptake. In contract, warming had no effect on soil N availability. These results suggest that the effects of warming on these grasslands will depend to a large extent on changes in amounts and timing of rainfall.

Last Modified: 10/25/2014