Estimation of transpiration fluxes from rainfed and irrigated sugarcane in South Africa using a canopy resistance and crop coefficient model

•A Jarvis-Stewart model calibrated for sugarcane can be applied for the prediction of hourly and daily transpiration.•Canopy resistance for optimal conditions is constant due to the increase of minimum stomatal resistance with LAI.•An analytical function was derived to express the response of sugarc...

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Veröffentlicht in:	Agricultural water management 2017-02, Vol.181, p.94-107
Hauptverfasser:	Bastidas-Obando, E., Bastiaanssen, W.G.M., Jarmain, C.
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Sprache:	eng
Schlagworte:	Calibration Canopies Coefficients Crop coefficient Crops Environmental stress Jarvis-Stewart model Mathematical models Stomata Stresses Sugar cane Sugarcane Transpiration
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description	•A Jarvis-Stewart model calibrated for sugarcane can be applied for the prediction of hourly and daily transpiration.•Canopy resistance for optimal conditions is constant due to the increase of minimum stomatal resistance with LAI.•An analytical function was derived to express the response of sugarcane transpiration to soil water conditions.•The Jarvis-Stewart model outperformed the classical FAO56 type crop coefficients when compared to field measurements. The area under sugarcane is rapidly growing worldwide. The consequences of such growth on basin scale water consumption and competing water resources need to be understood. Conventional models for sugarcane evapotranspiration have shown limitations for different environmental conditions. To improve current estimations of sugarcane water consumption, hourly and daily transpiration of rainfed sugarcane in Kwazulu-Natal (South Africa) and daily transpiration for irrigated sugarcane in Mpumalanga (South Africa) were calculated by using the Penman-Monteith equation (TPM) with a variable canopy resistance. Canopy resistance was calculated with the Jarvis-Stewart model from calibrated environmental stress functions. The classic FAO56 crop coefficient approach (TFAO56) was also investigated and crop coefficient values, crop basal coefficient and water stress coefficient were derived. There were differences between derived crop coefficient values and FAO56 weather-adjusted values. Derived crop basal coefficient (Kcb) was 0.9 for rainfed and irrigated sugarcane, which was lower than FAO56 weather-adjusted values of 1.19 for rainfed and 1.15 for irrigated at mid-stage. The reduction of the crop basal coefficient with the water stress coefficient resulted in an underestimation of transpiration for rainfed sugarcane. This indicates that water uptake under stress conditions is a complex process, not easy to model as water can be extracted from considerable depths. Daily estimates obtained from TPM outperformed those obtained from TFAO56 when compared to Bowen ratio and Surface Renewal system field measurements. For rainfed sugarcane with water-stressed conditions the TFAO56 RMSE was 1.55mmday−1 compared to 0.3mmday−1 for TPM. For rainfed sugarcane with water-unstressed conditions the TFAO56 RMSE was 0.5mmday−1 and the TPM RMSE was 0.22mmday−1 for TPM. For irrigated sugarcane the TPM RMSE of 0.47mmday−1 was slightly lower than the TPM RMSE of 0.49mmday−1, and TPM showed better correlation with an R2 of 0.85 compared t
doi_str_mv	10.1016/j.agwat.2016.11.024
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The area under sugarcane is rapidly growing worldwide. The consequences of such growth on basin scale water consumption and competing water resources need to be understood. Conventional models for sugarcane evapotranspiration have shown limitations for different environmental conditions. To improve current estimations of sugarcane water consumption, hourly and daily transpiration of rainfed sugarcane in Kwazulu-Natal (South Africa) and daily transpiration for irrigated sugarcane in Mpumalanga (South Africa) were calculated by using the Penman-Monteith equation (TPM) with a variable canopy resistance. Canopy resistance was calculated with the Jarvis-Stewart model from calibrated environmental stress functions. The classic FAO56 crop coefficient approach (TFAO56) was also investigated and crop coefficient values, crop basal coefficient and water stress coefficient were derived. There were differences between derived crop coefficient values and FAO56 weather-adjusted values. Derived crop basal coefficient (Kcb) was 0.9 for rainfed and irrigated sugarcane, which was lower than FAO56 weather-adjusted values of 1.19 for rainfed and 1.15 for irrigated at mid-stage. The reduction of the crop basal coefficient with the water stress coefficient resulted in an underestimation of transpiration for rainfed sugarcane. This indicates that water uptake under stress conditions is a complex process, not easy to model as water can be extracted from considerable depths. Daily estimates obtained from TPM outperformed those obtained from TFAO56 when compared to Bowen ratio and Surface Renewal system field measurements. For rainfed sugarcane with water-stressed conditions the TFAO56 RMSE was 1.55mmday−1 compared to 0.3mmday−1 for TPM. For rainfed sugarcane with water-unstressed conditions the TFAO56 RMSE was 0.5mmday−1 and the TPM RMSE was 0.22mmday−1 for TPM. For irrigated sugarcane the TPM RMSE of 0.47mmday−1 was slightly lower than the TPM RMSE of 0.49mmday−1, and TPM showed better correlation with an R2 of 0.85 compared to an R2 of 0.64 for TFAO56. This suggests that calibrated variables of the Jarvis-Stewart model for sugarcane proved to be suitable for both rainfed and irrigated sugarcane in South Africa. 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The area under sugarcane is rapidly growing worldwide. The consequences of such growth on basin scale water consumption and competing water resources need to be understood. Conventional models for sugarcane evapotranspiration have shown limitations for different environmental conditions. To improve current estimations of sugarcane water consumption, hourly and daily transpiration of rainfed sugarcane in Kwazulu-Natal (South Africa) and daily transpiration for irrigated sugarcane in Mpumalanga (South Africa) were calculated by using the Penman-Monteith equation (TPM) with a variable canopy resistance. Canopy resistance was calculated with the Jarvis-Stewart model from calibrated environmental stress functions. The classic FAO56 crop coefficient approach (TFAO56) was also investigated and crop coefficient values, crop basal coefficient and water stress coefficient were derived. There were differences between derived crop coefficient values and FAO56 weather-adjusted values. Derived crop basal coefficient (Kcb) was 0.9 for rainfed and irrigated sugarcane, which was lower than FAO56 weather-adjusted values of 1.19 for rainfed and 1.15 for irrigated at mid-stage. The reduction of the crop basal coefficient with the water stress coefficient resulted in an underestimation of transpiration for rainfed sugarcane. This indicates that water uptake under stress conditions is a complex process, not easy to model as water can be extracted from considerable depths. Daily estimates obtained from TPM outperformed those obtained from TFAO56 when compared to Bowen ratio and Surface Renewal system field measurements. For rainfed sugarcane with water-stressed conditions the TFAO56 RMSE was 1.55mmday−1 compared to 0.3mmday−1 for TPM. For rainfed sugarcane with water-unstressed conditions the TFAO56 RMSE was 0.5mmday−1 and the TPM RMSE was 0.22mmday−1 for TPM. For irrigated sugarcane the TPM RMSE of 0.47mmday−1 was slightly lower than the TPM RMSE of 0.49mmday−1, and TPM showed better correlation with an R2 of 0.85 compared to an R2 of 0.64 for TFAO56. This suggests that calibrated variables of the Jarvis-Stewart model for sugarcane proved to be suitable for both rainfed and irrigated sugarcane in South Africa. More research is needed to verify the validity of the calibrated stressed functions in other regions with high intensity of sugarcane plantations.</description><subject>Calibration</subject><subject>Canopies</subject><subject>Coefficients</subject><subject>Crop coefficient</subject><subject>Crops</subject><subject>Environmental stress</subject><subject>Jarvis-Stewart model</subject><subject>Mathematical models</subject><subject>Stomata</subject><subject>Stresses</subject><subject>Sugar cane</subject><subject>Sugarcane</subject><subject>Transpiration</subject><issn>0378-3774</issn><issn>1873-2283</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNqNUUFuFDEQtBBILIEXcPGRywz22DP2HDhEUQhIkXIInK2O3V68mrUH2wPkDzwab5Yz4tSq7qqWqoqQt5z1nPHp_aGH_U-o_dBAz3nPBvmM7LhWohsGLZ6THRNKd0Ip-ZK8KuXAGJNMqh35fV1qOEINKdLkac0QyxryeeGX7RcW6nM60gwhenQUoqMh57CH2lDZ9pAtRKQh0vu01W_00udggW4lxD0F2o5pfaQZSygVosWnDzanldqE3gcbMFZ6TA6X1-SFh6Xgm7_zgnz9eP3l6lN3e3fz-erytrNSs9o5HK0V4IWdRzfjBJzJUT6IUQxSwTChUtrBxB9mxAEc8mnykwKctJ-VlSguyLvz3zWn7xuWao6hWFyWZiRtxXCtGRMjG-b_oI6z1KPWolHFmdrMlZLRmzW3aPOj4cycajIH81STOdVkODetpqb6cFZhM_wjYDbllIhFFzLaalwK_9T_ARF0n6o</recordid><startdate>201702</startdate><enddate>201702</enddate><creator>Bastidas-Obando, E.</creator><creator>Bastiaanssen, W.G.M.</creator><creator>Jarmain, C.</creator><general>Elsevier B.V</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7QH</scope><scope>7SN</scope><scope>7ST</scope><scope>7TG</scope><scope>7UA</scope><scope>C1K</scope><scope>F1W</scope><scope>H96</scope><scope>H97</scope><scope>KL.</scope><scope>L.G</scope><scope>SOI</scope><scope>8FD</scope><scope>FR3</scope><scope>KR7</scope></search><sort><creationdate>201702</creationdate><title>Estimation of transpiration fluxes from rainfed and irrigated sugarcane in South Africa using a canopy resistance and crop coefficient model</title><author>Bastidas-Obando, E. ; Bastiaanssen, W.G.M. ; Jarmain, C.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c480t-de5cc3af3c95d9e6a10454b353247a26e778da61b9ee2ade166f67ae68f97c4e3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Calibration</topic><topic>Canopies</topic><topic>Coefficients</topic><topic>Crop coefficient</topic><topic>Crops</topic><topic>Environmental stress</topic><topic>Jarvis-Stewart model</topic><topic>Mathematical models</topic><topic>Stomata</topic><topic>Stresses</topic><topic>Sugar cane</topic><topic>Sugarcane</topic><topic>Transpiration</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Bastidas-Obando, E.</creatorcontrib><creatorcontrib>Bastiaanssen, W.G.M.</creatorcontrib><creatorcontrib>Jarmain, C.</creatorcontrib><collection>CrossRef</collection><collection>Aqualine</collection><collection>Ecology Abstracts</collection><collection>Environment Abstracts</collection><collection>Meteorological & Geoastrophysical Abstracts</collection><collection>Water Resources Abstracts</collection><collection>Environmental Sciences and Pollution Management</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy & Non-Living Resources</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 3: Aquatic Pollution & Environmental Quality</collection><collection>Meteorological & Geoastrophysical Abstracts - Academic</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><collection>Environment Abstracts</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Civil Engineering Abstracts</collection><jtitle>Agricultural water management</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Bastidas-Obando, E.</au><au>Bastiaanssen, W.G.M.</au><au>Jarmain, C.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Estimation of transpiration fluxes from rainfed and irrigated sugarcane in South Africa using a canopy resistance and crop coefficient model</atitle><jtitle>Agricultural water management</jtitle><date>2017-02</date><risdate>2017</risdate><volume>181</volume><spage>94</spage><epage>107</epage><pages>94-107</pages><issn>0378-3774</issn><eissn>1873-2283</eissn><abstract>•A Jarvis-Stewart model calibrated for sugarcane can be applied for the prediction of hourly and daily transpiration.•Canopy resistance for optimal conditions is constant due to the increase of minimum stomatal resistance with LAI.•An analytical function was derived to express the response of sugarcane transpiration to soil water conditions.•The Jarvis-Stewart model outperformed the classical FAO56 type crop coefficients when compared to field measurements. The area under sugarcane is rapidly growing worldwide. The consequences of such growth on basin scale water consumption and competing water resources need to be understood. Conventional models for sugarcane evapotranspiration have shown limitations for different environmental conditions. To improve current estimations of sugarcane water consumption, hourly and daily transpiration of rainfed sugarcane in Kwazulu-Natal (South Africa) and daily transpiration for irrigated sugarcane in Mpumalanga (South Africa) were calculated by using the Penman-Monteith equation (TPM) with a variable canopy resistance. Canopy resistance was calculated with the Jarvis-Stewart model from calibrated environmental stress functions. The classic FAO56 crop coefficient approach (TFAO56) was also investigated and crop coefficient values, crop basal coefficient and water stress coefficient were derived. There were differences between derived crop coefficient values and FAO56 weather-adjusted values. Derived crop basal coefficient (Kcb) was 0.9 for rainfed and irrigated sugarcane, which was lower than FAO56 weather-adjusted values of 1.19 for rainfed and 1.15 for irrigated at mid-stage. The reduction of the crop basal coefficient with the water stress coefficient resulted in an underestimation of transpiration for rainfed sugarcane. This indicates that water uptake under stress conditions is a complex process, not easy to model as water can be extracted from considerable depths. Daily estimates obtained from TPM outperformed those obtained from TFAO56 when compared to Bowen ratio and Surface Renewal system field measurements. For rainfed sugarcane with water-stressed conditions the TFAO56 RMSE was 1.55mmday−1 compared to 0.3mmday−1 for TPM. For rainfed sugarcane with water-unstressed conditions the TFAO56 RMSE was 0.5mmday−1 and the TPM RMSE was 0.22mmday−1 for TPM. For irrigated sugarcane the TPM RMSE of 0.47mmday−1 was slightly lower than the TPM RMSE of 0.49mmday−1, and TPM showed better correlation with an R2 of 0.85 compared to an R2 of 0.64 for TFAO56. This suggests that calibrated variables of the Jarvis-Stewart model for sugarcane proved to be suitable for both rainfed and irrigated sugarcane in South Africa. More research is needed to verify the validity of the calibrated stressed functions in other regions with high intensity of sugarcane plantations.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.agwat.2016.11.024</doi><tpages>14</tpages><oa>free_for_read</oa></addata></record>
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subjects	Calibration Canopies Coefficients Crop coefficient Crops Environmental stress Jarvis-Stewart model Mathematical models Stomata Stresses Sugar cane Sugarcane Transpiration
title	Estimation of transpiration fluxes from rainfed and irrigated sugarcane in South Africa using a canopy resistance and crop coefficient model
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