Decomposition of the finest root branching orders : linking belowground dynamics to fine-root function and structure

Marc Goebel, Sarah E. Hobbie, Bartosz Bulaj, Marcin Zadworny, Douglas D. Archibald, Jacek Oleksyn, Peter B. Reich, David M. Eissenstat

    Research output: Contribution to journalArticle

    169 Citations (Scopus)

    Abstract

    Root turnover is fastest in the finest roots of the root system (first root order). Additionally, tissue chemistry varies among even the finest root orders and between white roots and older, pigmented roots. Yet the effects of pigmentation and order on root decomposition have rarely been examined. We separated the first four root orders (all <1 mm) of four temperate tree species into three classes: white first- and second-order roots; pigmented first- and second-order roots; and pigmented third- and fourth-order roots. Roots were enclosed in litterbags and buried under their own and under a common species canopy in a 34-year-old common garden in Poland. When comparing decomposition of different root orders over 36 months, pigmented third- and fourth-order roots with a higher C:N ratio decomposed more rapidly, losing 20–40% of their mass, than pigmented first- and second-order roots, which lost no more than 20%. When comparing decomposition of roots of different levels of pigmentation within the same root order over 14 months, pigmented (older) first- and second-order roots lost 10% of their mass, while white (younger) first- and second-order roots lost 30%. In contrast to root mass loss, root N content declined more rapidly in the first- and second-order roots than in third- and fourth-order roots. In higher-order roots, N increased in the first 10 months from 110% to nearly 150% of initial N content, depending on species; by the end of the study N content had returned to initial levels. These findings suggest that, in plant communities where root mortality is primarily of pigmented first- and second-order roots, microbial decomposition may be slower than estimates derived from bulk fine-root litterbag experiments, which typically contain at least four root orders. Thus, a more mechanistic understanding of root decomposition and its contribution to ecosystem carbon and nutrient dynamics requires a fundamental shift in experimental methods that stratifies root samples for decomposition along more functionally based criteria such as root order and pigmentation, which parallel the markedly different longevities of these different root classes.
    Original languageEnglish
    Number of pages14
    JournalEcological Monographs
    Publication statusPublished - 2011

    Open Access - Access Right Statement

    © Copyright Ecological Society of America

    Keywords

    • biomass
    • decomposition
    • fine roots
    • litterbags
    • nitrogen
    • root pigmentation

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