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        <dc:title>Measuring And Modelling The Water Balance Of Low Rainfall Cropping Systems</dc:title>
        <dc:creator>Whitbread, A M</dc:creator>
        <dc:creator>Hoffmann, M P</dc:creator>
        <dc:creator>Davoren, C W</dc:creator>
        <dc:creator>Mowat, D</dc:creator>
        <dc:creator>Baldock, J A</dc:creator>
        <dc:subject>Climate Risk</dc:subject>
        <dc:subject>Cropping and Farming Systems</dc:subject>
        <dc:subject>Soil Science</dc:subject>
        <dc:description>In low-rainfall cropping systems, understanding the water balance, and in particular the storage of soil water&#13;
in the rooting zone for use by crops, is considered critical for devising risk management strategies for grain-based farming.&#13;
Crop-soil modeling remains a cost-effective option for understanding the interactions between rainfall, soil, and crop&#13;
growth, from which management options can be derived. The objective of this study was to assess the error in the prediction&#13;
of soil water content at key decision points in the season against continuous, multi-layer soil water measurements made&#13;
with frequency domain reflectometry (FDR) probes in long-term experiments in the Mallee region of South Australia and&#13;
New South Wales. Field estimates of the crop lower limit or drained upper limit were found to be more reliable than laboratory-&#13;
based estimates, despite the fact that plant-available water capacity (PAWC) did not substantially differ between the&#13;
methods. Using the Agricultural Production Systems sIMulator (APSIM) to simulate plant-available water over three-year&#13;
rotations, predicted soil water was within 7 mm (PAWC 64 to 99 mm) of the measured data across all sowing events and&#13;
rotations. Simulated (n = 46) wheat grain production resulted in a root mean square error (RMSE) of 492 kg ha-1, which is&#13;
only marginally smaller than that of other field studies that derived soil water limits with less detailed methods. This study&#13;
shows that using field-derived data of soil water limits and soil-specific settings for parameterization of other properties&#13;
that determine soil evaporation and water redistribution enables APSIM to be widely applied for managing climate risk in&#13;
low-rainfall environments.</dc:description>
        <dc:publisher>ASABE</dc:publisher>
        <dc:date>2017</dc:date>
        <dc:type>Article</dc:type>
        <dc:type>PeerReviewed</dc:type>
        <dc:format>application/pdf</dc:format>
        <dc:language>en</dc:language>
        <dc:identifier>http://oar.icrisat.org/10551/1/Whitbread_etal_Measuring%26Modelling_SoilWater_ASABE2017.pdf</dc:identifier>
        <dc:identifier>  Whitbread, A M and Hoffmann, M P and Davoren, C W and Mowat, D and Baldock, J A  (2017) Measuring And Modelling The Water Balance Of Low Rainfall Cropping Systems.  Transactions of the ASABE, 60 (6).  pp. 2097-2110.  ISSN 2151-0032     </dc:identifier>
        <dc:relation>https://doi.org/10.13031/trans.12581</dc:relation>
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