Microbial growth and respiration are at the core of the soil carbon (C) cycle, as these
microbial physiological performances ultimately determine the fate of soil C. Microbial C use …

Background Microbial contributions to soil organic carbon formation have received
increasing attention, and microbial carbon use efficiency is positively correlated with soil …

Climate-smart agriculture aims amongst others at protecting and increasing soil organic
carbon (SOC) stocks. The allocation of metabolised carbon (C) between soil microbial …

Understanding the response patterns and potential mechanisms of structure and function in
grassland ecosystems to nitrogen (N) enrichment is essential to evaluate ecological impacts …

While the responses of soil organic carbon (SOC) dynamics to atmospheric nitrogen (N)
deposition have been widely investigated, little is known in terms of if, and how the …

Soil pH is one of the main drivers of soil microbial functions, including carbon use efficiency
(CUE), the efficiency of microorganisms in converting substrate C into biomass, a key …

Soil microorganisms are the drivers of soil organic carbon (SOC) mineralization, and the
activities of these microorganisms are considered to play a key role in SOC dynamics …

摘要理解草地生态系统结构和功能对氮富集的响应及其机制有助于准确评估大气氮沉降等外源
氮输入的生态效应. 全球范围内建立的多水平氮添加实验为认识草地生态系统结构和功能对氮 …

Nitrogen (N) deposition has increased soil carbon (C) storage across eastern US temperate
forests by reducing microbial decomposition. However, the fate of these N-induced soil C …

As one of the most widespread driving forces in the world, atmospheric nitrogen (N)
deposition can significantly alter the carbon cycling of ecosystems. In order to understand …