Drying‐Off Periods for Irrigated Sugarcane to Maximize Sucrose Yields Under Brazilian Conditions

Dias, Henrique Boriolo; Sentelhas, Paulo César

doi:10.1002/ird.2263

Cited by 8 publications

(9 citation statements)

References 21 publications

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“…Better modelling of RGP will probably reduce the uncertainties in sugarcane simulations. For example, the drying-off days to increase sucrose yield in irrigated sugarcane estimated in Brazil (Dias and Sentelhas, 2018a), South Africa (Donaldson and Bezuidenhout, 2000) and Australia (Robertson et al, 1999) with APSIM-Sugar and CA-NEGRO models would be improved, since they used relative stalk dry mass as a trigger to withhold water before harvest. Several sugarcane yield gap analyses performed with crop models in Brazil (Dias and Sentelhas, 2018b;Marin et al, 2016;Monteiro and Sentelhas, 2017) and other countries (Cheeroo-Nayamuth et al, 2000;Van den Berg and Singels, 2013;Zu et al, 2018) did not take into account the RGP in the simulations.…”

Section: Tablementioning

confidence: 99%

“…The use of APSIM-Sugar has increased in Brazil recently. This model has been applied to evaluate the impact of a green cane trash blanket on yield (Costa et al, 2014;Marin et al, 2014;Oliveira et al, 2016), for irrigation planning (Dias and Sentelhas, 2018a), for yield gap analysis (Dias and Sentelhas, 2018b) and for uncertainties under climate change scenarios (Marin et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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New APSIM-Sugar features and parameters required to account for high sugarcane yields in tropical environments

Dias

Inman-Bamber

Bermejo³

et al. 2019

Field Crops Research

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Sugarcane in field plot experiments in tropical Brazil (Guadalupe, Piauí State, 6.6°S), produced very high yields under non-limiting water and nutrients. Mean stalk dry mass at 8, 11.5 and 15 months were 40, 51 and 70 t/ha respectively for six varieties and six planting dates. These yields were explained by high but not excessive temperatures allowing the canopy to close after 73 days on average. Substantial changes were required to enable the APSIM-Sugar model to simulate canopy and yield gain processes in Brazilian genotypes for the purpose of optimising variety, planting and harvest date options. A new modelling feature was proposed to deal with the observed growth slowdown when crop was about 7-8 months old and dry mass yields higher than 40 t/ha. All new parameters and features were validated with independent experiments as well as with the original dataset used for developing APSIM-Sugar. Future studies involving irrigation, yield gap analysis and climate change in environments where high yields are expected, should consider these modifications.

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Section: Tablementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

New APSIM-Sugar features and parameters required to account for high sugarcane yields in tropical environments

Dias

Inman-Bamber

Bermejo³

et al. 2019

Field Crops Research

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“…Being a year‐long crop, sugarcane requires continuous supply of IW throughout its growth cycle, and thus IW management is a very important aspect (Inman‐Bamber & McGlinchey, 2003; Singandhupe et al, 2008; Carr & Knox, 2011; Cardozo, de Oliveira, & La Scala, 2018; Dias & Sentelhas, 2018). Under such circumstances, deficit irrigation is inevitable (Garg & Dadhich, 2014; Bahmani & Eghbalian, 2018; Lucas et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Sugarcane response to different soil water replenishment‐based deficit irrigation treatments during different growth stages in an Indian semi‐arid region*

Dingre

Gorantiwar

Pawar

et al. 2021

Irrigation and Drainage

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The objective of this study was to investigate the effect of a specified water deficit during a specified growth stage by replenishing root zone soil water. A field experiment was conducted with 27 treatments in randomized block design comprising groupings of different root zone soil water replenishment levels (100%, 70%, and 40%) during different growth stages (tillering, grand growth, and maturity) over three full-year seasons of 2015-2017 in clay soils of semiarid western India. The full-season 100% soil water replenishment produced higher yield (174 t ha À1 ), net monetary returns, and benefit-cost (B:C) ratio that decreased linearly with linear decrease in water use. Full-season 40% soil water replenishment caused a reduction in yield of about 40.7%, whereas a 70% replenishment caused a reduction in yield by 14%. The quality parameters of sugarcane improved non-significantly in high-water-deficit conditions compared with full irrigation. The smaller range of water productivity in all seasons indicated a linear decrease when irrigation water increased and yields decreased under the different treatments. The net income and B:C ratio related to marketable cane yield was highest in 100% soil water replenishment (INR 274,000 ha À1 and 1.58, respectively) and then declined with the decrease in water use depth. The water deficit imposed during the long-duration grand growth stage had adverse effects on cane yield, followed by tillering and maturity stages. Deficit irrigation scheduling at 100%, 70%, and 40% soil water replenishment at tillering, grand growth, and maturity stages, respectively, was appropriate. The water requirement of seasonal sugarcane under full irrigation and water deficit conditions was 1,320 and 1,150 mm, respectively. K E Y W O R D S crop water use, economics, growth stages, quality of sugarcane, soil water replenishment, yield reduction * Réponse de la canne à sucre à différentes irrigations déficitaires basées sur la reconstitution de l'eau du sol à différents stades de croissance dans la région semi-aride indienne

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“…For example, the drying-off days to increase sucrose yield in irrigated sugarcane estimated in Brazil (Dias and Sentelhas, 2018a), South Africa (Donaldson and Bezuidenhout, 2000) and Australia (Robertson et al, 1999) with APSIM-Sugar and CANEGRO models would be improved, since they used relative stalk dry mass as a trigger to withhold water before harvest. Several sugarcane yield gap analyses performed with crop models in Brazil (Dias and Sentelhas, 2018b;Marin et al, 2016;Monteiro and Sentelhas, 2017) and other countries Jones and Singels, 2015;van den Berg and Singels, 2013;Zu et al, 2018) did not take into account the RGP in the simulations.…”

Section: Discussionmentioning

confidence: 99%

“…The use of APSIM-Sugar has increased in Brazil recently. This model has been applied to evaluate the impact of a green cane trash blanket on yield , for irrigation planning (Dias and Sentelhas, 2018a), for yield gap analysis (Dias and Sentelhas, 2018b) and for uncertainties under climate change scenarios .…”

Section: Thesis Overviewmentioning

confidence: 99%

Sugarcane variety trait modelling: evaluating and improving the APSIM-Sugar model for simulating crop performance under current and future climates across Brazil

Dias¹

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Sugarcane variety trait modelling: evaluating and improving the APSIM-Sugar model for simulating crop performance under current and future climates across Brazil Brazil is the largest sugarcane producer in the world and the production systems across the country are very complex with large spatial and temporal variations in yields. This is a result of large Genotype × Environment × Management (G × E × M) interactions that ultimately affect crop performance. Moreover, likely changes in the climate conditions are expected in the future imposing additional challenges to sugarcane production. Process-based crop modelling is scientifically accepted as a way to understand those interactions. Upon that, this thesis aimed to integrate field experiments datasets with the APSIM-Sugar model for better understanding the G × E × M interactions in Brazilian cropping systems. The capability of the model was first evaluated with default settings and then modifications and traits were proposed to effectively predict G (varieties) differences. With APSIM-Sugar upgraded, an up-to-date projection of future climate impacts on sugarcane yields across Brazil was performed. The sugarcane dataset came from large field experiments carried out between 2012 and 2017 at two tropical sites in Brazil: Guadalupe, in the state of Piauí (PI), and São Romão, in the state of Minas Gerais (MG), where several varieties were cultivated under non-limiting (potential) conditions. These data were analysed and employed to characterise variety traits for use in APSIM-Sugar. Substantial changes were required to enable the model to simulate canopy development and stalk yield appropriately. The outcomes from the modelling studies showed that the model is now able, although yet empirically, to account for ageing processes, known as the reduced growth phenomenon, to get better yield predictions in high yielding environments, as well as the ability to distinguish between varieties when it comes to yield gains above ~ 150 t/ha (~ 40 t/ha in dry mass). The findings suggest it is reasonable to hypothesise that the APSIM-Sugar modifications and traits are plausible and are an important step for unravelling G × E × M interactions to improve the performance of the sugarcane industry. Another step of this thesis, before applying APSIM-Sugar, was to evaluate gridded weather datasets (NASA/POWER and other developed for Brazil referred to 'XAVIER') as alternative climate inputs in the model. The results indicated these data sources should be employed with caution when the purpose is to simulate sugarcane yield because of the poor performance of gridded rainfall, at least for Center-South Brazil. Lastly, a climate change impact assessment was performed with APSIM-Sugar considering new features and traits for 10 Brazilian sites, being six under rainfed and four under fully-irrigated conditions. Five global climate models were selected to represent basic classes of climate changes: relatively cool/wet; cool/dry; middle; hot/wet; and hot/dry, for four future scenarios. These c...

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Drying‐Off Periods for Irrigated Sugarcane to Maximize Sucrose Yields Under Brazilian Conditions

Cited by 8 publications

References 21 publications

New APSIM-Sugar features and parameters required to account for high sugarcane yields in tropical environments

New APSIM-Sugar features and parameters required to account for high sugarcane yields in tropical environments

Sugarcane response to different soil water replenishment‐based deficit irrigation treatments during different growth stages in an Indian semi‐arid region*

Sugarcane variety trait modelling: evaluating and improving the APSIM-Sugar model for simulating crop performance under current and future climates across Brazil

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