Anthropogenic nitrogen (N) deposition is expected to increase substantially and
continuously in the future. Soil N availability regulates microbial communities and the …

Soil fungi and bacteria are the key players in the transformation and processing of carbon
and nutrients in terrestrial ecosystems, yet controls on their abundance and activity are not …

Both nitrogen deposition (ND) and microplastics (MPs) pose global change challenges. The
effects of MPs co-existing with ND on ecosystem functions are still largely unknown. Herein …

Soil microbes comprise a large portion of the genetic diversity on Earth and influence a large
number of important ecosystem processes. Increasing atmospheric nitrogen (N) deposition …

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 …

Global climate warming may induce a positive feedback through increasing soil carbon (C)
release to the atmosphere. Although warming can affect both C input to and output from soil …

In tea (Camellia sinensis) plantation areas, soil acidification mainly results from excessive
nitrogen fertilization. However, the proposed theoretical explanations for soil acidification …

Impacts of reactive nitrogen (N) inputs on ecosystem carbon (C) dynamics are highly
variable, and the underlying mechanisms remain unclear. Here, we proposed a new …

Soil microbes play an important role in ecosystem processes, including carbon (C) and
nutrient cycling. Nitrogen (N) enrichment is known to affect soil microbes, but whether other …

Nitrogen (N) enrichment poses threats to biodiversity and ecosystem stability, while
arbuscular mycorrhizal (AM) fungi play important roles in ecosystem stability and …