Studies on ecological stoichiometry (ES) have increased rapidly in number in recent years.
Continuous exploration of classical concepts such as the growth-rate hypothesis (GRH),) …

Global atmospheric nitrogen deposition significantly affects the nutrient cycling and C–N–P
stoichiometry in ecosystems. Herein, a global meta-analysis was conducted based on 898 …

How stoichiometry in different ecosystem components responds to long-term nitrogen (N)
addition is crucial for understanding within-ecosystem biogeochemistry cycling processes in …

Forests are the largest carbon sink in terrestrial ecosystems, and the impact of nitrogen (N)
deposition on this carbon sink depends on the fate of external N inputs. However, the …

Groundwater and its associated nutrients sustain the establishment and persistence of
phreatophytes. Rapid root elongation immediately after germination is vital for desert …

Fine roots (< 2 mm in diameter) play an important role in belowground ecosystem
processes, and their physiological ecology is easily altered by nitrogen deposition. To better …

Fine roots of woody plants comprise multiple root orders, which can be functionally
partitioned into two pools: absorptive fine roots (AFR s, orders 1, 2) and transport fine roots …

Fine roots play a crucial regulatory role in the subsurface carbon (C) and nitrogen (N) cycles
of terrestrial ecosystems and are potentially influenced by atmospheric N deposition …

The response of leaf functional traits can provide vital insight into the adaptive strategies of
plants under global change. However, empirical knowledge on the acclimation of functional …

Nitrogen (N) deposition usually increases plant tissue N concentrations and thus
phosphorus (P) demand in young and/or N‐limited forests, but the N deposition effect on …