Background and Aims Modelling organic matter decomposition is fundamental to understand biogeochemical cycling in terrestrial ecosystems. Current models use C/N or Lignin/N ratios to describe susceptibility to decomposition, or implement separate C pools decaying with different rates, disregarding biomolecular transformations and interactions and their effect on decomposition dynamics. We present a new process-based model of decomposition including a description of biomolecular dynamics obtained by 13C-CPMAS NMR spectroscopy. Methods Baseline decay rates for relevant molecular classes and intermolecular protection were calibrated by best fitting of experimental data from leaves of 20 plant species decomposing for 180 days in controlled optimal conditions. The model was validated against field data from leaves of 32 plant species decomposing for 1-year at four sites in Mediterranean ecosystems. Results Simulations correctly reproduced mass loss data and variations of selected molecular classes both in controlled conditions and in the field, for a wide range of plant molecular composition and environmental conditions. Conclusions Our innovative approach accurately predicted decomposition of a wide range of litters across different climates. Prediction accuracy emerged from the species-specific partitioning of molecular types and from the representation of intermolecular interactions. Further application should be planned in other ecosystems based on long-term decomposition datasets.

OMDY: a new model of organic matter decomposition based on biomolecular content as assessed by 13C-CPMAS-NMR / Incerti, Guido; Bonanomi, Giuliano; Giannino, Francesco; Carteni', Fabrizio; Spaccini, Riccardo; Mazzei, Pierluigi; Piccolo, Alessandro; Mazzoleni, Stefano. - In: PLANT AND SOIL. - ISSN 0032-079X. - 411:(2017), pp. 377-394. [10.1007/s11104-016-3039-2]

OMDY: a new model of organic matter decomposition based on biomolecular content as assessed by 13C-CPMAS-NMR

INCERTI, Guido;BONANOMI, GIULIANO;GIANNINO, FRANCESCO;CARTENI', FABRIZIO;SPACCINI, RICCARDO;MAZZEI, PIERLUIGI;PICCOLO, ALESSANDRO;MAZZOLENI, STEFANO
2017

Abstract

Background and Aims Modelling organic matter decomposition is fundamental to understand biogeochemical cycling in terrestrial ecosystems. Current models use C/N or Lignin/N ratios to describe susceptibility to decomposition, or implement separate C pools decaying with different rates, disregarding biomolecular transformations and interactions and their effect on decomposition dynamics. We present a new process-based model of decomposition including a description of biomolecular dynamics obtained by 13C-CPMAS NMR spectroscopy. Methods Baseline decay rates for relevant molecular classes and intermolecular protection were calibrated by best fitting of experimental data from leaves of 20 plant species decomposing for 180 days in controlled optimal conditions. The model was validated against field data from leaves of 32 plant species decomposing for 1-year at four sites in Mediterranean ecosystems. Results Simulations correctly reproduced mass loss data and variations of selected molecular classes both in controlled conditions and in the field, for a wide range of plant molecular composition and environmental conditions. Conclusions Our innovative approach accurately predicted decomposition of a wide range of litters across different climates. Prediction accuracy emerged from the species-specific partitioning of molecular types and from the representation of intermolecular interactions. Further application should be planned in other ecosystems based on long-term decomposition datasets.
2017
OMDY: a new model of organic matter decomposition based on biomolecular content as assessed by 13C-CPMAS-NMR / Incerti, Guido; Bonanomi, Giuliano; Giannino, Francesco; Carteni', Fabrizio; Spaccini, Riccardo; Mazzei, Pierluigi; Piccolo, Alessandro; Mazzoleni, Stefano. - In: PLANT AND SOIL. - ISSN 0032-079X. - 411:(2017), pp. 377-394. [10.1007/s11104-016-3039-2]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/642554
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