Altered plant carbon partitioning enhanced forest ecosystem carbon storage after 25 years of nitrogen additions

Summary Decades of atmospheric nitrogen (N) deposition in the northeastern USA have enhanced this globally important forest carbon (C) sink by relieving N limitation. While many N fertilization experiments found increased forest C storage, the mechanisms driving this response at the ecosystem scale...

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Bibliographic Details
Published in:The New phytologist 2021-05, Vol.230 (4), p.1435-1448
Main Authors: Eastman, Brooke A., Adams, Mary B., Brzostek, Edward R., Burnham, Mark B., Carrara, Joseph E., Kelly, Charlene, McNeil, Brenden E., Walter, Christopher A., Peterjohn, William T.
Format: Article
Language:English
Subjects:
Acquisition
Biogeochemistry
Biological fertilization
Biomass
Carbon
Carbon capture and storage
carbon cycling
Carbon sequestration
Ecosystem
experimental N addition
Fertilization
Forest ecosystems
Forests
Litter
N acquisition strategies
Nitrogen
optimal allocation theory
Partitioning
plant biomass allocation
Soil
Soil testing
Soils
Stocks
Symbionts
temperate forest
terrestrial carbon sink
Terrestrial ecosystems
Trees
Vegetation
Watersheds
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Summary:Summary Decades of atmospheric nitrogen (N) deposition in the northeastern USA have enhanced this globally important forest carbon (C) sink by relieving N limitation. While many N fertilization experiments found increased forest C storage, the mechanisms driving this response at the ecosystem scale remain uncertain. Following the optimal allocation theory, augmented N availability may reduce belowground C investment by trees to roots and soil symbionts. To test this prediction and its implications on soil biogeochemistry, we constructed C and N budgets for a long‐term, whole‐watershed N fertilization study at the Fernow Experimental Forest, WV, USA. Nitrogen fertilization increased C storage by shifting C partitioning away from belowground components and towards aboveground woody biomass production. Fertilization also reduced the C cost of N acquisition, allowing for greater C sequestration in vegetation. Despite equal fine litter inputs, the C and N stocks and C : N ratio of the upper mineral soil were greater in the fertilized watershed, likely due to reduced decomposition of plant litter. By combining aboveground and belowground data at the watershed scale, this study demonstrates how plant C allocation responses to N additions may result in greater C storage in both vegetation and soil.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.17256