B51K-03
Linking Belowground Plant Traits With Ecosystem Processes: A Multi-Biome Perspective
Friday, 18 December 2015: 08:30
2010 (Moscone West)
Colleen M. Iversen1, Richard J Norby1, Joanne Childs1, M. Luke McCormack2, Anthony P Walker1, Paul J Hanson1, Jeff Warren1, Victoria L Sloan3, Patrick F Sullivan4, Stan Wullschleger1 and A. Shafer Powell1, (1)Oak Ridge National Laboratory, Oak Ridge, TN, United States, (2)University of Minnesota Twin Cities, Minneapolis, MN, United States, (3)ORNL, Bristol, United Kingdom, (4)University of Alaska Anchorage, Anchorage, AK, United States
Abstract:
Fine plant roots are short-lived, narrow-diameter roots that play an important role in ecosystem carbon, water, and nutrient cycling in biomes ranging from the tundra to the tropics. Root ecologists make measurements at a millimeter scale to answer a question with global implications: In response to a changing climate, how do fine roots modulate the exchange of carbon between soils and the atmosphere and how will this response affect our future climate? In a Free-Air CO2 Enrichment experiment in Oak Ridge, TN, elevated [CO2] caused fine roots to dive deeper into the soil profile in search of limiting nitrogen, which led to increased soil C storage in deep soils. In contrast, the fine roots of trees and shrubs in an ombrotrophic bog are constrained to nutrient-poor, oxic soils above the average summer water table depth, though this may change with warmer, drier conditions. Tundra plant species are similarly constrained to surface organic soils by permafrost or waterlogged soils, but have many adaptations that alter ecosystem C fluxes, including aerenchyma that oxygenate the rhizosphere but also allow direct methane flux to the atmosphere. FRED, a global root trait database, will allow terrestrial biosphere models to represent the complexity of root traits across the globe, informing both model representation of ecosystem C and nutrient fluxes, but also the gaps where measurements are needed on plant-soil interactions (for example, in the tropical biome). While the complexity of mm-scale measurements may never have a place in large-scale global models, close collaboration between empiricists and modelers can help to guide the scaling of important, yet small-scale, processes to quantify their important roles in larger-scale ecosystem fluxes.