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Chemical Composition of High Organic Carbon Soil Amendments Affects Fertilizer-Derived N2O Emission and Nitrogen Immobilization in an Oxic Sandy Loam

Jing Wei, Rüdiger Reichel, Muhammad Saiful Islam, Holger Wissel, Wulf Amelung, Nicolas Brüggemann

2020Frontiers in Environmental Science27 citationsDOIOpen Access PDF

Abstract

Nitrous oxide (N2O) emission is a negative side effect of modern agriculture and a serious issue for global climate change. The combined application of nitrogen (N) fertilizer and high organic carbon soil amendments (HCA) has been regarded as an alternative to promote fertilizer-related N immobilization and enhance nitrogen use efficiency. The effect of HCA on N2O emission and N immobilization highly depends on its chemical composition, as it controls carbon (C) supply to soil microbes and reactivity of lignin-derived phenols to fertilizer-derived N species. Here we present a 127-d laboratory incubation study to explore the N2O emission and N immobilization after combined application of N fertilizer and HCA (wheat straw, spruce sawdust, and commercial alkali lignin) differing in their chemical composition. The 15N labelling technique was used to trace the transformation of fertilizer-N in ammonium (NH4+), NO3-, soil organic nitrogen (SON), and N2O. The amendment of wheat straw and spruce sawdust greatly promoted N immobilization and N2O emission, while lignin amendment enhanced the immobilization of fertilizer N. The chemical composition of HCA explained 26% of the total variance of fertilizer-derived N2O emission and N retention via soil microbial biomass, composition of lignin-derived phenols, and nitrification. The holocellulose/lignin ratio of HCA could be used as an indicator for predicting HCA decomposition, microbial N immobilization and N2O emission. In addition, the composition of lignin-derived phenols was affected by HCA amendment and significantly related to N2O emission and N retention. The varying chemical composition of HCA could thus be a promising tool for controlling N2O emission and N immobilization in environment-friendly and climate-smart agriculture.

Topics & Concepts

FertilizerChemistryLigninAmendmentStrawSawdustLoamNitrogenEnvironmental chemistryAgronomySoil conditionerBiomass (ecology)Soil waterEnvironmental scienceOrganic chemistryInorganic chemistrySoil scienceBiologyPolitical scienceLawSoil Carbon and Nitrogen DynamicsPlant nutrient uptake and metabolismSoil and Water Nutrient Dynamics
Chemical Composition of High Organic Carbon Soil Amendments Affects Fertilizer-Derived N2O Emission and Nitrogen Immobilization in an Oxic Sandy Loam | Litcius