Nitrogen (N) and phosphorus (P) are associated with the life history of all organisms. Soil
microbes play essential roles in nutrient cycling and ecosystem dynamics. As compared to …

Aim To investigate broad‐scale patterns of soil microbial nitrogen (N) and phosphorus (P)
stoichiometry and their environmental drivers. Location Global forests. Methods By …

Increased soil nitrogen (N) from atmospheric N deposition could change microbial
communities and functions. However, the underlying mechanisms and whether soil …

Soil microorganisms are a key driver of changes in soil organic matter and nutrient cycling.
Changes in growth, turnover, and carbon use efficiency (CUE) of soil microbial communities …

Background and aims Human activities have significantly increased nitrogen (N) and
phosphorous (P) inputs to terrestrial ecosystems. However, the impact of N and P …

Microorganisms mediate nutrient cycling in soils, and thus it is assumed that they largely
control responses of terrestrial ecosystems to anthropogenic nutrient inputs. Therefore, it is …

Rapid increase of nitrogen (N) deposition could alter nutrient availability, leading to changes
in soil microbial processes and ecosystem carbon and nutrient cycling. However, the effects …

Microbial nitrogen use efficiency (NUE), which reflects the proportion of nitrogen (N) taken
up to be allocated to microbial biomass and growth, is central to our understanding of soil N …

Anthropogenic activities have dramatically increased nitrogen (N) and phosphorous (P)
enrichments in terrestrial ecosystems. However, it is still unclear on how bacterial and fungal …

Aim To estimate the concentrations, stoichiometry and storage of soil microbial biomass
carbon (C), nitrogen (N) and phosphorus (P) at biome and global scales. Location Global …