Experimental nitrogen fertilisation globally accelerates, then slows decomposition of leaf litter

Allison Gill; Jonathan Schilling; Sarah E. Hobbie

doi:10.1111/ele.13700

Experimental nitrogen fertilisation globally accelerates, then slows decomposition of leaf litter

Allison Gill, Jonathan Schilling, Sarah E. Hobbie

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Abstract

Plant litter decomposition is a central process in the carbon (C) cycle and sensitive to ongoing anthropogenic nitrogen (N) fertilisation. Previous syntheses evaluating the effect of N fertilisation on litter decomposition relied largely on models that define a constant rate of mass loss throughout decomposition, which may mask hypothesised shifts in the effect of N fertilisation on litter decomposition dynamics. In this meta-analysis, we compared the performance of four empirical decomposition models and showed that N fertilisation consistently accelerates early-stage but slows late-stage decomposition when the model structure allows for flexibility in decomposition rates through time. Within a particular substrate, early-stage N-stimulation of decomposition was associated with reduced rates of late-stage decay. Because the products of early- vs. late-stage decomposition are stabilised in soils through distinct chemical and physical mechanisms, N-induced changes in the litter decomposition process may influence the formation and cycling of soil C, the largest terrestrial C pool.

Original language	English (US)
Pages (from-to)	802-811
Number of pages	10
Journal	Ecology letters
Volume	24
Issue number	4
DOIs	https://doi.org/10.1111/ele.13700
State	Published - Apr 2021

Bibliographical note

Funding Information:
Members of the Hobbie Research Group, EJ Sayer and three anonymous reviewers provided comments which improved this manuscript. Funding support was provided by the Grand Challenges in Biology Postdoctoral Fellowship Program from the University of Minnesota (to ALG), and the NSF Long‐Term Ecological Research (DEB‐1234162) and Ecosystem Studies (DEB‐1556529) Programs.

Publisher Copyright:
© 2021 John Wiley & Sons Ltd.

Keywords

Calcium
decomposition model
lignin
meta-analysis
necromass
soil organic matter

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abstract = "Plant litter decomposition is a central process in the carbon (C) cycle and sensitive to ongoing anthropogenic nitrogen (N) fertilisation. Previous syntheses evaluating the effect of N fertilisation on litter decomposition relied largely on models that define a constant rate of mass loss throughout decomposition, which may mask hypothesised shifts in the effect of N fertilisation on litter decomposition dynamics. In this meta-analysis, we compared the performance of four empirical decomposition models and showed that N fertilisation consistently accelerates early-stage but slows late-stage decomposition when the model structure allows for flexibility in decomposition rates through time. Within a particular substrate, early-stage N-stimulation of decomposition was associated with reduced rates of late-stage decay. Because the products of early- vs. late-stage decomposition are stabilised in soils through distinct chemical and physical mechanisms, N-induced changes in the litter decomposition process may influence the formation and cycling of soil C, the largest terrestrial C pool.",

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Experimental nitrogen fertilisation globally accelerates, then slows decomposition of leaf litter

Abstract

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Keywords

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