Economic assessment at farm level of the implementation of deficit irrigation for quinoa production in the Southern Bolivian Altiplano

Cusicanqui, Jorge; Dillen, Koen; Garcia, Magalı́; Geerts, Sam; Raes, Dirk; Mathijs, Erik

doi:10.5424/sjar/2013114-4097

Cited by 12 publications

(7 citation statements)

References 40 publications

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“…Due to quinoa's water use efficiency, halophytic properties, and wide genetic diversity, the crop can survive in an extreme range of temperatures (−4 to 38 °C), frost, low rainfall (as little as 50 mm/y), nutrient‐poor soils with pH ranging from 6.0 to 8.5, and high salinity (40 mS/cm) (Hellin and Higman ; Valencia‐Chamorro ; Bhargava and others ; Hariadi and others ; Vega‐Galvez and others ; FAO ). In fact, the largest global production region of quinoa is the Salar de Uyuni (salt flats of Oruro and Potosí provinces in Bolivia), where quinoa is the only crop capable of withstanding the extreme environmental conditions (Cusack ; FAO ; Cusicanqui and others ).…”

Section: Ethnobotanical Overview Of Quinoamentioning

confidence: 99%

Innovations in Health Value and Functional Food Development of Quinoa (Chenopodium quinoa Willd.)

Graf

Rojas-Silva

Rojo

et al. 2015

Comp Rev Food Sci Food Safe

238

190

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Quinoa (Chenopodium quinoa Willd., Amaranthaceae) is a grain-like, stress-tolerant food crop that has provided subsistence, nutrition, and medicine for Andean indigenous cultures for thousands of years. Quinoa contains a high content of health-beneficial phytochemicals, including amino acids, fiber, polyunsaturated fatty acids, vitamins, minerals, saponins, phytosterols, phytoecdysteroids, phenolics, betalains, and glycine betaine. Over the past 2 decades, numerous food and nutraceutical products and processes have been developed from quinoa. Furthermore, 4 clinical studies have demonstrated that quinoa supplementation exerts significant, positive effects on metabolic, cardiovascular, and gastrointestinal health in humans. However, vast challenges and opportunities remain within the scientific, agricultural, and development sectors to optimize quinoa's role in the promotion of global human health and nutrition.

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Section: Ethnobotanical Overview Of Quinoamentioning

confidence: 99%

Innovations in Health Value and Functional Food Development of Quinoa (Chenopodium quinoa Willd.)

Graf

Rojas-Silva

Rojo

et al. 2015

Comp Rev Food Sci Food Safe

238

190

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“…An example was set by Dunan et al (1994Dunan et al ( , 1999, who optimized weed management based on both agronomic and economic aspects. Moreover, the linkage of AquaCrop to economic models has been demonstrated by García-Vila et al (2009), García-Vila & Fereres (2012) and Cusicanqui et al (2013).…”

Section: Model Applicationmentioning

confidence: 88%

Simulation of crop production in weed-infested fields for data-scarce regions

et al. 2016

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SUMMARYWeed infestation is a major yield-reducing factor that also decreases crop water productivity. Yet weeds are often neglected in crop productivity simulation studies, because existing empirical equations and mechanistic models are not widely applicable or have a high demand for input data and calibration. For that reason, AquaCrop, a widely applicable crop water productivity model, was expanded with a weed management module which requires only two easily obtainable input variables: (i) relative leaf cover of weeds, and (ii) weed-induced increase of total canopy cover. Using these inputs, AquaCrop directly simulates soil water content, crop canopy development and production as it is observed in weed-infested fields. Despite this simple approach, AquaCrop performed well to simulate soil water content in the root zone (relative root-mean-square error (RRMSE) of 5–13%), canopy cover (RRMSE of 15–22%), dry above-ground crop biomass during the season (RRMSE of 21–39%) and at maturity (RRMSE of 5–6%) and yield (RRMSE of 11–25%) of barley and wheat grown under different weed infestation levels and environments. The current study illustrates that the AquaCrop model can be used to assess the effect of weed infestation on crop growth and production, using a simple approach that is applicable to diverse environmental and agronomic conditions, even in data-scarce regions.

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“…Finally, it is clear that after analysing the agronomic benefits of different field management strategies using AquaCrop, a socio-economic analysis is indispensable. Following the examples of García-Vila et al (2009), García-Vila & Fereres (2012) and Cusicanqui et al (2013), who optimized irrigation management both from an agronomic and an economic point of view, it is clear that AquaCrop simulation results can be coupled to economic models so as to analyse the effect of the soil fertility management strategies on labour requirements and farmers’ profits.…”

Section: Discussionmentioning

confidence: 99%

A semi-quantitative approach for modelling crop response to soil fertility: evaluation of the AquaCrop procedure

et al. 2014

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Most crop models make use of a nutrient-balance approach for modelling crop response to soil fertility. To counter the vast input data requirements that are typical of these models, the crop water productivity model AquaCrop adopts a semi-quantitative approach. Instead of providing nutrient levels, users of the model provide the soil fertility level as a model input. This level is expressed in terms of the expected impact on crop biomass production, which can be observed in the field or obtained from statistics of agricultural production. The present study is the first to describe extensively, and to calibrate and evaluate, the semi-quantitative approach of the AquaCrop model, which simulates the effect of soil fertility stress on crop production as a combination of slower canopy expansion, reduced maximum canopy cover, early decline in canopy cover and lower biomass water productivity. AquaCrop's fertility response algorithms are evaluated here against field experiments with tef (Eragrostis tef (Zucc.) Trotter) in Ethiopia, with maize (Zea mays L.) and wheat (Triticum aestivum L.) in Nepal, and with quinoa (Chenopodium quinoa Willd.) in Bolivia. It is demonstrated that AquaCrop is able to simulate the soil water content in the root zone, and the crop's canopy development, dry above-ground biomass development, final biomass and grain yield, under different soil fertility levels, for all four crops. Under combined soil water stress and soil fertility stress, the model predicts final grain yield with a relative root-mean-square error of only 11–13% for maize, wheat and quinoa, and 34% for tef. The present study shows that the semi-quantitative soil fertility approach of the AquaCrop model performs well and that the model can be applied, after case-specific calibration, to the simulation of crop production under different levels of soil fertility stress for various environmental conditions, without requiring detailed field observations on soil nutrient content

show abstract

Economic assessment at farm level of the implementation of deficit irrigation for quinoa production in the Southern Bolivian Altiplano

Cited by 12 publications

References 40 publications

Innovations in Health Value and Functional Food Development of Quinoa (Chenopodium quinoa Willd.)

Innovations in Health Value and Functional Food Development of Quinoa (Chenopodium quinoa Willd.)

Simulation of crop production in weed-infested fields for data-scarce regions

A semi-quantitative approach for modelling crop response to soil fertility: evaluation of the AquaCrop procedure

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