Environmental Toxicology and Ecological Risk Assessment

Biography

Biography: Maria Arlene Adviento-Borbe

Abstract

Improved N fertilizer management practices can reduce greenhouse gas (GHG) emissions while maintain high grain yields. Field studies were initiated in California, Arkansas and Nebraska to determine GHG emission mitigation potential of different N fertilizer management practices that aimed to optimize yield in irrigated rice and maize cropping systems. Grain yield and GHG emissions were quantified from rice and maize fields with various fertilizer sources (i.e. urea, aqua ammonia, ammonium nitrate/sulfate) and applications (i.e. surface subsurface) at 100 to 310 kg N ha^-1 rates. Emissions of CH₄ and N₂O for rice and CO₂ and N₂O for maize were measured using flux chamber and gas chromatography or photo-acoustic spectroscopy. At all sites, rice yields were 2.9 to 11.9 Mg ha^-1 in unfertilized fields and increased by 117% in fertilized fields. Maize yields increased by 22% compared to yields from recommended N rates and were within 80-100% of estimated site yield potential. CH₄ emissions and CO₂ and N₂O emissions were the main sources of GWP in rice and maize, respectively. In some cases, higher N rates increased total CH₄ emissions in rice and total N₂O emissions in maize field. However, GWP from rice fields had no clear patterns among different N applications and GWP emissions were minimal in maize field under intensive practice. Our study shows that GHG emissions from maize cropping can be reduced when management is implemented towards efficient N fertilization. For rice cropping, further assessments are needed to determine if strategies to increase yield can potentially mitigate GHG emissions.