Samuel Thies scite author profile

The impact of interactions between management and climate on nitrous oxide (N2O), carbon dioxide (CO2), and ammonia (NH3) emissions are not well understood. This study quantified the effect of urea fertilizer application timing on inorganic N movement, immobilization, and the gaseous emissions of N2O‐N, CO2‐C, and NH3‐N. Urea was applied once, at two rates (0 and 224 kg ha−1) on six dates (early fall, 20 Sept. 2017; mid‐fall, 11 Oct. 2017; early winter, 1 Nov. 2017; early spring, 1 May 2018; mid‐spring, 22 May 2018; and early summer, 12 June 2018). Gaseous emissions, soil temperature, and soil moisture were measured every 4 h for 21 consecutive days following urea application. Changes in soil inorganic N contents were used to determine the amount of inorganic N remaining in the soil, nitrification, immobilization/fixation, and leaching. For all fertilizer application dates, the cumulative fertilizer derived N2O‐N emissions for the 21 days following application were <0.05% of the applied N. Fertilizer‐derived N2O‐N emission rates were higher than N2O‐N emission rates in the unfertilized soil in early fall and early summer. Even though the highest net N2O‐N emissions occurred in early spring, the application of fertilizer did not increase emissions. The highest net N2O‐N + NH3‐N emissions occurred in cool soils (early spring) in soils with water filled pore space (>60%). These findings indicate that intergovernmental panel on climate change (IPCC) default value of 1% of applied N for N2O emissions improved by considering the fertilizer application date.

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Agents Concerned with Natural Crossing of Cotton in Oklahoma¹

Thies¹

1953

Agronomy Journal

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Midmorning Point Sampling May Not Accurately Represent Nitrous Oxide Emissions Following Fertilizer Applications

Thies

Bruggeman

Clay

et al. 2019

Soil Science Soc of Amer J

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Midmorning N2O flux estimates were not consistent with near‐continual data for spring and fall applied urea. Local N2O sampling protocols must account for temporal changes in management and climatic conditions. Non‐alignment in soil temperature and N2O patterns in annual‐crop soils is consistent with Fick's Law. Non‐alignment between temperatuer and N2O emissions can occur when the soil is saturated with water. Near‐continuous automated data collection at anticipated max and min emissions may improve the accuracy of N2O estimates. A common approach for measuring N2O emissions is to collect midmorning or early evening gas samples from experiments utilizing the chamber‐based flux methodology. However, due to high spatial and temporal variability, N2O estimates based on midmorning or early evening sampling may not provide accurate estimates of total emissions. This study determined the impact of sampling collection timing on the precision and accuracy of N2O emissions estimates. Nitrous oxide emissions, air and soil temperatures, and soil moisture were measured for 21 d following the application of 224 kg urea‐N ha–1 on 20 Sept. 2017, 11 Oct. 2017, and 1 May 2018, at six time intervals (0130–0230, 0530–0630, 0930–1030, 1330–1430, 1730–1830, and 2130–2230 h) over a 24‐h period. Based on multiple daily measurements, point samples collected between 0930 and 1030 h (midmorning) were inconsistent in their ability to predict N2O emissions. However, samples collected between 2130 and 2230 h (early evening) were similar to average emissions. The number of randomly collected point samples to be within 20% of the mean 80% of the time over a 21‐d period ranged from 13 samples for fertilizer applied on 20 Sept. 2017 to 48 samples for fertilizer applied on 11 Oct. 2017. This research indicates that management and climatic variability affect N2O emissions, and that accurate sampling protocols vary across management and climates. To reduce uncertainty, N2O sampling protocol should be tested under conditions likely to occur and where possible, near‐continuous measurement systems should be adopted.

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Samuel Thies

Fertilizer timing affects nitrous oxide, carbon dioxide, and ammonia emissions from soil

Agents Concerned with Natural Crossing of Cotton in Oklahoma¹

Midmorning Point Sampling May Not Accurately Represent Nitrous Oxide Emissions Following Fertilizer Applications

Contact Info

Product

Resources

About

Samuel Thies

Fertilizer timing affects nitrous oxide, carbon dioxide, and ammonia emissions from soil

Agents Concerned with Natural Crossing of Cotton in Oklahoma1

Midmorning Point Sampling May Not Accurately Represent Nitrous Oxide Emissions Following Fertilizer Applications

Contact Info

Product

Resources

About

Agents Concerned with Natural Crossing of Cotton in Oklahoma¹