Abstract
Biogeochemical models such as Daily-
DayCent (DDC) are increasingly used to help quantify
the emissions of green-house gasses across different
ecosystems and climates. For this use they require
parameterisation to represent a heterogeneous region
or are site specific and scaled upwards. This requires
information on inputs such as climate, soil, land-use
and land management. However, each input has an
associated uncertainty, which propagates through the
model to create an uncertainty in the modelled outputs.
To have confidence in model projections, an assessment
of how the uncertainty in inputs propagated
through the model and its impact on modelled outputs is required. To achieve this, we used a pre-defined
uncertainty range of key inputs; temperature, precipitation,
clay content, bulk density and soil pH, and
performed a sensitivity and uncertainty analysis, using
Monte Carlo simulations. This allowed the effect of
measurement uncertainty on the modelled annual N2O
emissions and crop yields at the Grange field experimental
site to be quantified. Overall the range of model
estimates simulated was relatively high and while the
model was sensitive to each input parameter, uncertainty
was driven by the sensitivity to soil pH. This
decreased as the N fertiliser application rate increased,
as at lower N application rates the model becomes
more sensitive to other drivers ofNmineralisation such
as soil and climate inputs. Therefore, while our results
indicate that DDC can provide a good estimate of
annual N2O emissions and crop yields under UK
conditions, reducing the uncertainty in the input
parameters will lead to more accurate simulations.
Original language | English |
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Pages (from-to) | 119 - 133 |
Number of pages | 15 |
Journal | Nutrient Cycling in Agroecosystems |
Volume | 99 |
Issue number | 1-3 |
DOIs | |
Publication status | First published - 2014 |
Bibliographical note
2047560Keywords
- Crop yield
- DailyDayCent
- Monte Carlo simulations
- N2O emissions
- Sensitivity analysis