Research Project:
AGRICULTURAL SOIL EROSION AND CARBON CYCLE OBSERVATIONS: GAPS THREATEN CLIMATE MITIGATION POLICIES
Project Number: 3625-11610-001-13
Project Type: Reimbursable
1. Quantify the differences in soil carbon sequestration potential within the Clear Creek Amana Hydrologic Observatory (a second-order watershed) under different agricultural management practices; especially, we will measure the short-term dynamic fluxes of carbon as a function of crop, tillage management, antecedent water content, and a wide range of runoff conditions. 2. Through 12C/13C isotope ratio measurements in Eastern Iowa, resolve the relative effects of soil respiration, land cover (C3 or C4 plants), and crop rotation on soil and canopy carbon isotope ratios. 3. Refine spatially distributed models and make predictions of carbon transport and fluxes over larger, integrated watersheds and over decadal periods. In this way, we will determine the sensitivity of regional-scale carbon observation networks to the range of carbon fluxes found in objective 1. We will use what is learned in objectives 1 and 2 to relate changes in biogeochemical processes of production, decomposition, preservation, and burial of carbon in landscapes with a variety of chemical and biological characteristics, and changes in these processes with time. 4. Complement the on-the-ground measurements with remote sensed CO2 (from satellite and LIDAR) to in-situ samples from tall tower and aircraft, and to state-of-the-art atmospheric CO2 simulation results; the CO2 fluxes are necessary to capture terrestrial carbon cycle responses to climate variability and to improve carbon model simulations.
Project Type: Reimbursable
Start Date: Aug 01, 2010
End Date: Jul 31, 2013
Objective:
1. Quantify the differences in soil carbon sequestration potential within the Clear Creek Amana Hydrologic Observatory (a second-order watershed) under different agricultural management practices; especially, we will measure the short-term dynamic fluxes of carbon as a function of crop, tillage management, antecedent water content, and a wide range of runoff conditions. 2. Through 12C/13C isotope ratio measurements in Eastern Iowa, resolve the relative effects of soil respiration, land cover (C3 or C4 plants), and crop rotation on soil and canopy carbon isotope ratios. 3. Refine spatially distributed models and make predictions of carbon transport and fluxes over larger, integrated watersheds and over decadal periods. In this way, we will determine the sensitivity of regional-scale carbon observation networks to the range of carbon fluxes found in objective 1. We will use what is learned in objectives 1 and 2 to relate changes in biogeochemical processes of production, decomposition, preservation, and burial of carbon in landscapes with a variety of chemical and biological characteristics, and changes in these processes with time. 4. Complement the on-the-ground measurements with remote sensed CO2 (from satellite and LIDAR) to in-situ samples from tall tower and aircraft, and to state-of-the-art atmospheric CO2 simulation results; the CO2 fluxes are necessary to capture terrestrial carbon cycle responses to climate variability and to improve carbon model simulations.
Approach:
Studies will be conducted to compare the carbon balance across the Clear Creek and Walnut Creek watersheds in Iowa. These two different sites represent two different landforms within Iowa and different erosion characteristics. The studies will address the carbon exchange through direct measurements of the carbon balance along with indirect measurements through the C12/C13 ratios to compare with the soil respiration and CO2 exchange in plant canopies. The coupling of the ground-based measurements with the aircraft and satellite measurements of CO2 fluxes will be compared with spatial and temporal models for these two areas.
Last Modified:
8/13/2014