Effects of inhibitors and pig manure on the transformation of urea nitrogen in paddy soil

doi:10.13287/j.1001-9332.202006.026

Abstract

Abstract: With the aim to understand the response of different nitrogen forms in paddy soil under the conditions of urea combined with inhibitors and pig manure, and to explore the nitrogen retention and supply capacity of paddy soil under different management strategy, we conducted a pot experiment with ¹⁵N labeled urea. There were six treatments: no nitrogen fertilizer (CK), pig manure (M), urea (N), urea+pig manure (NM), urea+inhibitor (NI), urea+inhibitor+pig manure (NIM). Urease inhibitor (PPD+NBPT) and nitrification inhibitor (DMPP) were used as the inhibitor combination. Soil nitrogen pools, conservation of ¹⁵N labeled urea, and rice N adsorption were measured in rice seedling, tillering, and mature stages. Results showed that pig manure significantly increased soil ammonium concentration, soil microbial biomass nitrogen and fixed ammonium, as well as the storage of urea nitrogen in various pools at tillering stage, and significantly increased rice yield. Addition of the inhibitors increased NH₄⁺ fixation by clay minerals and nitrogen immobilization by microorganisms compared with treatment N, and increased urea-derived NH₄⁺ fixation by clay minerals compared with treatment NM. Pathway analysis showed that pig manure increased urea-N assimilation and yield of rice. The urea-derived ammonium fixed by clay minerals was temporarily stored after inhibitors application. NIM treatment stored more N in microbial biomass, and the released ammonium coupled the turnover and mineralization of microbial provided more available nitrogen for the later growth of rice. Both NM and NIM treatments are recommended in paddy fields of north China.

YU Chun-xiao, ZHANG Li-li, YANG Li-jie, LI Wen-tao, WU Kai-kuo, XIE Xue-shi, LI Dong-po, WU Zhi-jie. Effects of inhibitors and pig manure on the transformation of urea nitrogen in paddy soil[J]. Chinese Journal of Applied Ecology, 2020, 31(6): 1851-1858.

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