Nitrogen (N) fertilization is a pivotal contributor to increasing crop yields. The substantial
long-term effects of fertilization on soil microbial communities have been clearly verified …

Long‐term elevated nitrogen (N) input from anthropogenic sources may cause soil
acidification and decrease crop yield, yet the response of the belowground microbial …

Globally increasing nitrogen (N) deposition is recognized as an important regulator of soil
microbial communities. However, how N enrichment affects soil microbial diversity, richness …

It has been predicted that precipitation and atmospheric nitrogen (N) deposition will increase
in northern China; yet, ecosystem responses to the interactive effects of water and N remain …

Soil bacterial communities are pivotal in regulating terrestrial biogeochemical cycles and
ecosystem functions. The increase in global nitrogen (N) deposition has impacted various …

Little has been reported on the effects of long-term fertilization on rhizosphere soil microbial
diversity. Here, we investigated the effects of long-term continuous nitrogen (N) fertilization …

Ecosystems worldwide are receiving increasing amounts of reactive nitrogen (N) through
anthropogenic activities. Although the effects of increased N inputs on plant communities …

Soil microbes represent one of the most important members of agricultural systems, and
many achievements about the variation of microbiota in topsoil under diverse fertilization …

Soil abiotic and biotic interactions govern important ecosystem processes. However, the
mechanisms behind these interactions are complex, and the links between specific …

Although the effects of nitrogen (N) fertilization on soil microflora have been well studied, the
effects should be verified across soil types and N-added levels. To understand the impacts …