Lancaster EPrints

N14C:a plant-soil nitrogen and carbon cycling model to simulate terrestrial ecosystem responses to atmospheric nitrogen deposition

Tipping, Edward and Rowe, E. C. and Evans, Claire D. and Mills, Robert T. E. and Emmett, Bridget A. and Chaplow, J. S. and Hall, Jeremy R. (2012) N14C:a plant-soil nitrogen and carbon cycling model to simulate terrestrial ecosystem responses to atmospheric nitrogen deposition. Ecological Modelling, 247. pp. 11-26. ISSN 0304-3800

Full text not available from this repository.

Abstract

The dynamic model N14C simulates changes in the plant-soil dynamics of nitrogen and carbon, brought about by the anthropogenic deposition of nitrogen. The model operates with four plant functional types; broadleaved and coniferous trees, herbs and dwarf shrubs. It simulates net primary production (NPP). C and N pools, leaching of dissolved organic carbon and nitrogen (DOC, DON) and inorganic nitrogen, denitrification, and the radiocarbon contents of organic matter, on an annual timestep. Soil organic matter (SOM) comprises three pools, undergoing first-order decomposition reactions with turnover rates ranging from c. 2 to c. 1000 years. Nitrogen immobilisation by SOM occurs if inorganic N remains after plant uptake, and leaching of inorganic N occurs if the immobilisation demand is met. SOM accumulates in the deeper soil by transport and sorption of DOM. Element soil pools accumulate with N inputs by fixation from 12,000 years ago until 1800, when anthropogenic N deposition begins. We describe the parameterisation of N14C with data from 42 published plot studies carried out in northern Europe, plus more general information on N deposition trends, soil radiocarbon, N fixation and denitrification. A general set of 12 parameters describing litter fractionation. N immobilisation, growing season length, DOC and DON leaching, denitrification and NH4 retention was derived by fitting the field data. This provided fair agreements between observations and simulations, which were appreciably improved by moderate (+/-20%) adjustments of the parameters for specific sites. The parameterised model gives reasonable blind predictions of ecosystem C and N variables from only temperature, precipitation, N deposition, and vegetation type. The results suggest an approximate doubling of NPP due to N deposition, although the majority of the sites remain N-limited. For a given N deposition, leaching rates of inorganic N at conifer and shrub sites exceed those at broadleaf and herb sites. (C) 2012 Elsevier B.V. All rights reserved.

Item Type: Article
Journal or Publication Title: Ecological Modelling
Uncontrolled Keywords: Atmospheric deposition ; Carbon ; Leaching ; NPP ; Nitrogen ; Radiocarbon ; Soil ; Turnover ; DISSOLVED ORGANIC-CARBON ; TEMPERATE FOREST ECOSYSTEMS ; LITTER DECOMPOSITION ; NATURAL ECOSYSTEMS ; EUROPEAN FORESTS ; FOLIAR NITROGEN ; GLOBAL PATTERNS ; N-DEPOSITION ; MATTER ; SATURATION
Subjects:
Departments: Faculty of Science and Technology > Lancaster Environment Centre
Faculty of Health and Medicine > Health Research
ID Code: 74782
Deposited By: ep_importer_pure
Deposited On: 29 Jul 2015 14:40
Refereed?: Yes
Published?: Published
Last Modified: 18 Dec 2017 07:07
Identification Number:
URI: http://eprints.lancs.ac.uk/id/eprint/74782

Actions (login required)

View Item