Unravelling the age of fine roots of temperate and boreal forests

Fine roots support the water and nutrient demands of plants and supply carbon to soils. Quantifying turnover times of fine roots is crucial for modeling soil organic matter dynamics and constraining carbon cycle–climate feedbacks. Here we challenge widely used isotopebased estimates suggesting the t...

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Bibliographic Details
Published in:Nature Communications
Main Authors: Solly, Emily F., Brunner, Ivano, Helmisaari, Heljä-Sisko Marketta, Herzog, Claude, Leppälammi-Kujansuu, Jaana, Schöning, Ingo, Schrumpf, Marion, Schweingruber, Fritz H, Trumbore, Susan E., Hagedorn, Frank
Other Authors: Department of Forest Sciences, Forest Soil Science, Doctoral Programme in Sustainable Use of Renewable Natural Resources, Forest Ecology and Management
Format: Article in Journal/Newspaper
Language:English
Published: Nature Publishing Group 2018
Subjects:
4112 Forestry
ECTOMYCORRHIZA L FUNGI
NONSTRUCTURAL CARBON
OLD CARBON
SCOTS PINE
RADIOCARBON
TURNOVER
TREES
ECOSYSTEMS
VEGETATION
SEEDLINGS
ECTOMYCORRHIZAL FUNGI
Arctic
Online Access:http://hdl.handle.net/10138/238492
Description
Summary:Fine roots support the water and nutrient demands of plants and supply carbon to soils. Quantifying turnover times of fine roots is crucial for modeling soil organic matter dynamics and constraining carbon cycle–climate feedbacks. Here we challenge widely used isotopebased estimates suggesting the turnover of fine roots of trees to be as slow as a decade. By recording annual growth rings of roots from woody plant species, we show that mean chronological ages of fine roots vary from <1 to 12 years in temperate, boreal and sub-arctic forests. Radiocarbon dating reveals the same roots to be constructed from 10 ± 1 year (mean ± 1 SE) older carbon. This dramatic difference provides evidence for a time lag between plant carbon assimilation and production of fine roots, most likely due to internal carbon storage. The high root turnover documented here implies greater carbon inputs into soils than previously thought which has wide-ranging implications for quantifying ecosystem carbon allocation. Peer reviewed

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