Your search keyword '"KOLOUTSOU- VAKAKIS, SOTIRIA"' showing total 2 results

1. Evaluation of DeNitrification DeComposition model for estimating ammonia fluxes from chemical fertilizer application.

Author

Balasubramanian, Srinidhi, Koloutsou-Vakakis, Sotiria, Lin, Jie, Rood, Mark J., Nelson, Andrew, Myles, LaToya, and Bernacchi, Carl

Subjects

*DENITRIFICATION, *AMMONIA & the environment, *FERTILIZER application, *SENSITIVITY analysis, *ANALYSIS of covariance

Abstract

DeNitrification DeComposition (DNDC) model predictions of NH 3 fluxes following chemical fertilizer application were evaluated by comparison to relaxed eddy accumulation (REA) measurements, in Central Illinois, United States, over the 2014 growing season of corn. Practical issues for evaluating closure were addressed by accounting for fluxes outside the measurement site and differences in temporal resolution. DNDC modeled NH 3 fluxes showed no significant differences in magnitude (at p = 0.05) compared to measurements and replicated trends satisfactorily (r a 2 > 0.74), during the initial 33 days after fertilizer application, when measured fluxes were to the atmosphere, compared to later time periods when depositional fluxes were measured (r a 2 < 0.52). Among the model input parameters, NH 3 fluxes were most sensitive to air temperature, precipitation, soil organic carbon, field capacity, pH, and fertilizer application rate, timing, and depth. By constraining these inputs for conditions in Central Illinois, uncertainty in daily NH 3 fluxes was estimated to vary from 0% to 70% on a daily basis, during the corn growing season, with the highest uncertainty values estimated for the period of highest positive NH 3 fluxes. These results can guide future improvements in DNDC, which is a valuable tool to assist (1) in the development of NH 3 emission inventories with high spatial (constrained by the spatial resolution of input parameters) and temporal resolution (daily) and (2) in upscaling emissions from the site (farm) to the regional scale. [ABSTRACT FROM AUTHOR]

Published

2017

2. Ammonia flux measurements above a corn canopy using relaxed eddy accumulation and a flux gradient system.

Author

Nelson, Andrew J., Lichiheb, Nebila, Koloutsou-Vakakis, Sotiria, Rood, Mark J., Heuer, Mark, Myles, LaToya, Joo, Eva, Miller, Jesse, and Bernacchi, Carl

Subjects

*AMMONIA & the environment, *PLANT canopies, *CORN farming, *FERTILIZER application, *SOIL temperature

Abstract

Highlights • Inter-comparison of relaxed eddy accumulation and flux gradient measurements. • Strong correlation between the two NH 3 flux measurement methods. • Peak NH 3 flux measured with both systems six days after fertilizer application. • Two elevated emission periods influenced by urease inhibitor and environmental conditions. Abstract Studies of NH 3 flux over agricultural ecosystems in the USA are limited by low temporal resolution (typically hours or days) and sparse spatial coverage, with no studies over corn in the Midwest USA. We report on NH 3 flux measurements over a corn canopy in Central Illinois, USA, using the relaxed eddy accumulation (REA) and flux gradient (FG) methods, providing measurements at 4 h and 0.5 h intervals, respectively. The REA and FG systems were operated for the duration of the 2014 corn-growing season. Flux-footprint analysis was used to select data from both systems, resulting in 82 concurrent measurements. Mean NH 3 flux of concurrent measurements was 205 ± 300 ng m−2 s−1 from REA and 110 ± 256 ng m−2 s−1 from FG for all concurrent samples. Results from both methods were not significantly different at a 95% confidence level for all concurrent measurements. The FG system resolved NH 3 emission peaks at 0.5 h averaging time that were otherwise un-observed with 4 h REA averaging. Two early-season peak emission periods were identified (DOY 130-132 and 140-143), where the timing and intensity of such emissions were attributed to a combination of urease inhibitor, applied as a field-management decision, and localized soil temperature and precipitation. Given the dependence of NH 3 fluxes on multiple parameters, this study further highlights the need for increased spatial coverage and high temporal resolution (e.g., <1 h) of measurements to better understand the impact of agricultural NH 3 emissions on air quality and the global nitrogen cycle. Such measurements are also needed for evaluation of models describing surface-atmosphere exchange of NH 3. [ABSTRACT FROM AUTHOR]

Published

2019