Enhanced nitrogen (N) availability in temperate forests has altered ecosystem carbon (C)
and N cycling. Recent research has shown that these alterations lead to reductions in …

Forest soils harbor diverse microbial communities responsible for the cycling of elements
including carbon (C), nitrogen (N), and phosphorus (P). Conversely, anthropogenic N …

Soil appears to play a key role in the response of the forest ecosystems to N deposition.
Twenty years of experimental moderate N addition in a sub-alpine forest increased nitrate …

Composting, planting, and breeding waste for return to the field is the most crucial soil
improvement method under the resource utilization of agricultural waste. However, how the …

Nitrogen (N) fertilization has enhanced the forest land carbon (C) sink by increasing the
amount of C stored in soils, possibly through reductions in decomposition. Established …

Recent advocacy for Integrated Soil Fertility Management (ISFM) in smallholder farming
systems in east and southern Africa show substantial evidence of increased and sustained …

Damage by wind in forests has increased in recent decades, counteracting possible growth
increases by nitrogen (N) deposition. This is also shown by the long-term forest monitoring …

Purpose Anthropogenic activities have increased the nitrogen (N) inputs in terrestrial
ecosystems, thereby altering both the carbon (C) and phosphorus (P) availability along with …

Temperate deciduous forest ecosystems in northeastern North America are under
increasing biotic and abiotic stresses that can have interactive effects on understory …

Manganese (Mn) has been identified as a regulatory bottleneck in carbon (C) turnover
because of its role as an enzymatic co-factor in the oxidative decomposition of C by Mn …