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

Precipitation changes modify C, N, and P cycles, which regulate the functions and structure
of terrestrial ecosystems. Although altered precipitation affects above‐and belowground C …

The elevational pattern of soil microbial diversity along mountain slopes has received
considerable interest over the last decade. An increasing amount of taxonomic data on soil …

The impact of climate change on the soil microbiome potentially alters the biogeochemical
cycle of terrestrial ecosystems. In semi‐arid environments, water availability is a major …

Uneven-aged silvicultural practices can maintain habitat continuity and enhance
biodiversity. Soil microorganisms play critical roles in multiple ecosystem functions (ie …

Soil pH is a dominant factor affecting bacterial community composition in acidic, neutral, and
alkaline soils but not in severely acidic soils (pH< 4.5). We conducted a nitrogen (N) addition …

Aim Climate change intensifies the hydrological cycle and consequently alters precipitation
regimes. Accurately assessing future carbon (C) budgets depends on understanding the …

Desert microbes are expected to be substantially sensitive to global environmental changes,
such as precipitation changes and elevated nitrogen deposition. However, the effects of …

Plant community composition can alter soil microbial community structure and function, and
further influence the process of soil N transformation. However, this effect is rarely noticed in …

Food systems need to become more sustainable. There is a need to investigate the
agricultural management components that address the sustainability better. Long crop …