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Atmospheric deposition and sulphur cycling in chalk grasslandA mechanistic model simulating field observations (1990)

Dam, D. ; Heil, G. W. ; Heijne, B. ; [et al.]

Springer

Biogeochemistry 9 (1990), S. 19-38

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ISSN: 1573-515X

Keywords: acid rain ; atmospheric deposition ; chalk grassland ; simulation model ; throughfall ; sulphur cycling

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Geosciences

Notes: Abstract Sulphate fluxes in bulk deposition, throughfall and soil solution were monitored during two years, and integrated within a model describing the cycling of S in a chalk grassland ecosystem. Throughfall fluxes were strongly determined by interceptive properties of the grassland canopy. Seasonal variation in Leaf Area Index resulted in dry deposition velocities for SO2 varying between 0.1 cm.s−1 (snow cover, almost no aerodynamic resistance) to 0.9–1.8 cm.s−1 in periods with a fully developed canopy. On an annual basis net canopy exchange (assimilation of SO2 minus foliar leaching) was estimated to be −15% of net throughfall. Simulated soil solution concentrations, being the result of throughfall input, leaching, adsorption, biomass uptake and mineralization, closely fitted actual values (r 〉 0.92; p 〉 0.001). Actual and simulated leaching were 1.74 ± 0.03 and 2.00 keq.-ha−1.yr−1, respectively. Sulphur budgets for the soil showed net accumulation from April to October and net losses from October to April. Annual budgets for the ecosystem showed atmospheric input (2.02keq.ha−1.yr−1) and actual output (2.05keq.ha−1.yr−1) to be almost balanced. Apart from increased soil solution concentrations, additional input of sulphate (3.55 keq.ha−1.yr−1) to experimental plots resulted in additional accumulation in the ecosystem of 0.62 keq.ha−1.yr−1

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00002715

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Modelling the Impact of Lowered Atmospheric Nitrogen Deposition on a Nitrogen Saturated Forest Ecosystem (1998)

Koopmans, C. J. ; Van Dam, D.

Springer

Water, air & soil pollution 104 (1998), S. 181-203

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ISSN: 1573-2932

Keywords: coniferous ecosystems ; Douglas fir ; 15N ; NICCCE ; NITREX ; nitrogen ; simulation model

Source: Springer Online Journal Archives 1860-2000

Topics: Energy, Environment Protection, Nuclear Power Engineering

Notes: Abstract For a Douglas fir forest ecosystem subjected to an experimental decrease in nitrogen (N) deposition, N dynamics were simulated using the dynamic simulation model NICCCE. Meteorological driving variables and N concentrations in throughfall were input to the model, that simulated results of a 15N tracer experiment, C and N concentrations in the soil, soil water chemistry and tree biomass. Four years of ambient N deposition, followed by four years of N deposition manipulations by means of a roof construction beneath the forest canopy, were modelled. Simulation of this second period was performed for a high-N treatment (37 kg N ha-1 yr-1) and a low-N treatment with throughfall-N at natural background level (6 kg N ha-1 yr-1). Calibration and model performance is discussed and compared to results of field experiments. The quick response of soil water chemistry after lowering N deposition and the 15N tracer signal observed in soil water at 90 cm soil depth, were simulated closely by the calibrated model. 15NH4-N data could only be simulated by accounting for bypass flow, indicating that throughfall water did not fully interact with the soil. Using the calibrated parameter set of the low-N treatment for the high-N treatment resulted in a lower model performance, although time trends were reproduced well also for this treatment. A sensitivity analysis showed model outcome of N transformations to be very sensitive to soil microbial parameters, such as the C efficiency. Use of the 15N tracer data in the calibration lowered uncertainties of these sensitive model parameters. Evaluation of the N input-output budget and microbial N transformations in the ecosystem revealed that lowering N inputs in this N saturated forest soil resulted in a more than proportional decrease of N leaching losses out of the soil system. Gross N transformations decreased under lowered N input, in particular the formation of NO3-N. Net N mineralization was not affected after four years of N manipulations. Net nitrification was decreased to about one third of the rate observed at the high-N deposition plot. Combining 15N tracer data with dynamic simulation modelling provides a powerful tool to improve model performance and process descriptions, and to evaluate impacts of atmospheric N deposition on N cycling in ecosystems.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1004992614988

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