Estudo comparativo de coeficientes de cultura (Kc) para o manejo de irrigação do milho obtidos experimentalmente e estimados pelo manual FAO/56.

2016

Effect of irrigation amounts applied with subsurface drip irrigation on corn evapotranspiration, yield, water use efficiency, and dry matter production in a semiarid climate

Quantifying the local crop response to irrigation is important for establishing adequate irrigation management strategies. This study evaluated the effect of irrigation applied with subsurface drip irrigation on field corn (Zea mays L.) evapotranspiration (ETc), yield, water use efficiencies (WUE = yield/ETc, and IWUE = yield/irrigation), and dry matter production in the semiarid climate of west central Nebraska. Eight treatments were imposed with irrigation amounts ranging from 53 to 356 mm in 2005 and from 22 to 226 mm in 2006. A soil water balance approach (based on FAO-56) was used to estimate daily soil water and ETc. Treatments resulted in seasonal ETc of 580-663 mm and 466-656 mm in 2005 and 2006, respectively. Yields among treatments differed by as much as 22% in 2005 and 52% in 2006. In both seasons, irrigation significantly affected yields, which increased with irrigation up to a point where irrigation became excessive. Distinct relationships were obtained each season. Yields increased linearly with seasonal ETc (R 2 = 0.89) and ETc/ETp (R 2 = 0.87) (ETp = ETc with no water stress). The yield response factor (ky), which indicates the relative reduction in yield to relative reduction in ETc, averaged 1.58 over the two seasons. WUE increased non-linearly with seasonal ETc and with yield. WUE was more sensitive to irrigation during the drier 2006 season, compared with 2005. Both seasons, IWUE decreased sharply with irrigation. Irrigation significantly affected dry matter production and partitioning into the different plant components (grain, cob, and stover). On average, the grain accounted for the majority of the above-ground plant dry mass (≈59%), followed by the stover (≈33%) and the cob (≈8%). The dry mass of the plant and that of each plant component tended to increase with seasonal ETc. The good relationships obtained in the study between crop performance indicators and seasonal ETc demonstrate that accurate estimates of ETc on a daily and seasonal basis can be valuable for making tactical in-season irrigation management decisions and for strategic irrigation planning and management.

AQUAMAN: a web-based decision support system for irrigation scheduling in peanuts

Peanut (Arachis hypogaea L.) is an economically important legume crop in irrigated production areas of northern Australia. Although the potential pod yield of the crop in these areas is about 8 t ha(-1), most growers generally obtain around 5 t ha(-1), partly due to poor irrigation management. Better information and tools that are easy to use, accurate, and cost-effective are therefore needed to help local peanut growers improve irrigation management. This paper introduces a new web-based decision support system called AQUAMAN that was developed to assist Australian peanut growers schedule irrigations. It simulates the timing and depth of future irrigations by combining procedures from the food and agriculture organization (FAO) guidelines for irrigation scheduling (FAO-56) with those of the agricultural production systems simulator (APSIM) modeling framework. Here, we present a description of AQUAMAN and results of a series of activities (i.e., extension activities, case studies, and a survey) that were conducted to assess its level of acceptance among Australian peanut growers, obtain feedback for future improvements, and evaluate its performance. Application of the tool for scheduling irrigations of commercial peanut farms since its release in 2004-2005 has shown good acceptance by local peanuts growers and potential for significantly improving yield. Limited comparison with the farmer practice of matching the pan evaporation demand during rain-free periods in 2006-2007 and 2008-2009 suggested that AQUAMAN enabled irrigation water savings of up to 50% and the realization of enhanced water and irrigation use efficiencies.

三江源区人工草地蒸散量与气候因子的相关分析

该研究以小型自动气象站观测资料为基础,采用FAO Penman-Monteith方法估算三江源区人工草地参考作物蒸散量,并结合FAO-56推荐的综合作物系数值进行草地实际蒸散量的计算,分析了三江源区人工草地实际蒸散量的变化及其与气象因子的关系。结果表明,草地实际蒸散量的季节变化为单峰曲线,夏季日蒸散量明显大于冬季,在8月中旬达到年度最高值。蒸散与空气温度、太阳辐射和相对湿度均显著相关,但与风速的相关性不显著。各气象因子对人工草地蒸散量影响的大小顺序为:空气温度(T)>太阳辐射(Ra)>空气相对湿度(RH)>风速(u2)。

祁连山北坡草地蒸散量及其与影响因子的关系

【目的】研究祁连山北坡草地蒸散与其环境因子的关系，为该牧区草场的科学经营、草地退化的防治以及区域草地生态环境建设等提供科学依据。【方法】以小型自动气象站（HOBO Weather Station，U．S．A）气象观测资料为基础，采用FAO Penman-Monteith方法估算了祁连山北坡草地参考作物蒸散量（ET_0），并结合FAO-56的推荐值，分析了草地实际蒸散量（ETc）的动态变化，同时模拟研究了相关环境因子对实际蒸散量的影响。【结果】夏季（7和8月）草地的实际蒸散量较大，冬季（12和1月）较小，在7月中旬达到年度最高值，平均为3．40mm／d；按相关系数的高低，环境因子对实际蒸散量的影响表现为空气温度〉空气相对湿度〉土壤含水量（0～40cm）〉太阳辐射〉风速；土壤水分对实际蒸散量的影响表现为土壤深度越大，土壤水分对实际蒸散量的影响越小；太阳辐射量与实际蒸散量呈线性关系。【结论】祁连山北坡草地实际蒸散量的年际变化符合当地环境的变化规律，环境因子对其不同程度的影响表明，在今后的草场管理、退化防止、生态建设中应采取适的措施，以确保草地的良性发展。

Estimativa da evapotranspiração de referência com uso do Irrigâmetro em Vitória da conquista/BA

The Irrigameter is aevapotranspiration measuring device used in irrigation management to optimize water. However, its use requires a prior adjustment to weather conditions where it will be used. The objective of this study was identify the corresponding height of water level inside the evaporimeterIrrigameter that estimate reference evapotranspiration in climate of the plateau of Vitoria da Conquista - BA, in different seasons. The experiment was a completely randomized design with five treatments and three replications. For each treatment was determined an average coefficient for the Irrigameter called K I, calculated as the ratio of estimated evapotranspiration in Irrigameter (ET I) and reference evapotranspiration (ET 0). The ET 0 was obtained by the Penman-Monteith - FAO 56. The results showed that the coefficients of Irrigameter increased exponentially with increasing water level inside the evaporimeter, and the equipment must be operated with the water level equal to 5.2 cm for better estimation of ET 0. The remaining heights observed in different seasons showed no significant difference when compared to annual average used as a reference in this study.

Determinação da acurácia de instrumentos de medidas para obter a evapotranspiração de referência com erros fixados

Pós-graduação em Agronomia (Ciência do Solo) - FCAV

Substrato e irrigação em ora-pro-nóbis (Pereskia aculeata Mill.)

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Caracterização climática e comparação de métodos de estimativa de evapotranspiração de referência para regiões do Estado do Ceará

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Evapotranspiração e eficiência do uso da água no primeiro ciclo produtivo da figueira 'Roxo de valinhos' submetida a cobertura morta

Evaluated the evapotranspiration (ETc) and the efficiency of water use (USA) by the fig tree 'Purple Valinhos' submitted to irrigation and mulching (bagacilho of sugar cane crushed) in the first production cycle, at conditions of Botucatu, St. Paul. We used the method of soil water balance and to obtain the reference evapotranspiration method was used Montheit FAO Penman 56. For the assessment of crop coefficients (kc) we adopted the following phenological distribution: phase 1 - between transplanting and 20% of the vegetative (DV), ii) phase 2 - 20 to 80% DV, and iii) phase 3 - fruiting. Observe the cumulative ETc 409.4 and 465.8 mm in 254 days after transplanting (DAT) and averages of 1.47 and 1.67 mm day(-1), with and without mulching (CC and SC). The crop coefficients (kc) mediums were 0.16, 0.43 and 0.49 for SC and 0.18, 0.44 and 0.50 for CC, in phases 1 and 3, respectively. The EUA values decrease with increasing the volume of water received and ranged between 1.65 and 3.32 kg of green figs per m(3) of water for irrigated SC and CC.

Calibración del modelo de Hargreaves para la estimación de la evapotranspiración de referencia en Coronel Dorrego, Argentina

La Organización de las Naciones Unidas para la Agricultura y la Alimentación FAO propone el uso de la ecuación de Penman-Monteith (PM) como el estándar para la estimación de la evapotranspiración de referencia y para la calibración de otras ecuaciones. El principal inconveniente del uso de esta ecuación es que requiere datos que no se tienen en la mayoría de las estaciones. El uso de métodos de cálculos alternativos es usual en la bibliografía. El método de Hargreaves (HG), recomendado por la FAO, es el más usado en la bibliografía cuando sólo se dispone de los datos de temperaturas. El principal objetivo de este trabajo es analizar la posibilidad de calibración y ajuste del método HG en la estación de Coronel Dorrego. Se han comparado los métodos PM y HG, encontrándose una buena correlación entre ambos. Se concluye que el modelo HG es una metodología adecuada, para la zona de Coronel Dorrego y se sugiere la fórmula siguiente: ETo HG = 0,00206⋅Ra⋅(Tmáx-- T mín) 0,49⋅(tm+17,8) mm/día

Future reference evapotranspiration in Duero Valley (Spain)

The impact of climate change and its relation with evapotranspiration was evaluated in the Duero River Basin (Spain). The study shows the possible future situations 50 years from now from the reference evapotranspiration (ETo). The maximum temperature (Tmax), minimum temperature (Tmin), dew point (Td), wind speed (U) and net radiation (Rn) trends during the 1980-2009 period were obtained and extrapolated with the FAO-56 Penman- Montheith equation to estimate ETo. Changes in stomatal resistance in response to increases in CO2 were also considered. Four scenarios were done, considering the concentration of CO2 and the period analyzed (annual or monthly). The scenarios studied showed the changes in ETo as a consequence of the annual and monthly trends in the variables Tmax, Tmin, Td, U and Rn with current and future CO2 concentrations (372 ppm and 550 ppm). The future ETo showed increases between 118 mm (11%) and 55 mm (5%) with respect to the current situation of the river basin at 1042 mm. The months most affected by climate change are May, June, July, August and September, which also coincide with the maximum water needs of the basin?s crops

Trends in climatic variables and future reference evapotranspiration in Duero Valley (Spain)

The impact of climate change and its relation with evapotranspiration was evaluated in the Duero River Basin (Spain). The study shows possible future situations 50 yr from now from the reference evapotranspiration (ETo). The maximum temperature (Tmax), minimum temperature (Tmin), dew point (Td), wind speed (U) and net radiation (Rn) trends during the 1980–2009 period were obtained and extrapolated with the FAO-56 Penman-Montheith equation to estimate ETo. Changes in stomatal resistance in response to increases in CO2 were also considered. Four scenarios were done, taking the concentration of CO2 and the period analyzed (annual or monthly) into consideration. The scenarios studied showed the changes in ETo as a consequence of the annual and monthly trends in the variables Tmax, Tmin, Td, U and Rn with current and future CO2 concentrations (372 ppm and 550 ppm). The future ETo showed increases between 118 mm (11 %) and 55 mm (5 %) with respect to the current situation of the river basin at 1042 mm. The months most affected by climate change are May, June, July, August and September, which also coincide with the maximum water needs of the basin’s crops

Testing of crop Models for Accurate Predictions of Evapotranspiration and crop Water Use

All crop models, whether site-specific or global-gridded and regardless of crop, simulate daily crop transpiration and soil evaporation during the crop life cycle, resulting in seasonal crop water use. Modelers use several methods for predicting daily potential evapotranspiration (ET), including FAO-56, Penman-Monteith, Priestley-Taylor, Hargreaves, full energy balance, and transpiration water efficiency. They use extinction equations to partition energy to soil evaporation or transpiration, depending on leaf area index. Most models simulate soil water balance and soil-root water supply for transpiration, and limit transpiration if water uptake is insufficient, and thereafter reduce dry matter production. Comparisons among multiple crop and global gridded models in the Agricultural Model Intercomparison and Improvement Project (AgMIP) show surprisingly large differences in simulated ET and crop water use for the same climatic conditions. Model intercomparisons alone are not enough to know which approaches are correct. There is an urgent need to test these models against field-observed data on ET and crop water use. It is important to test various ET modules/equations in a model platform where other aspects such as soil water balance and rooting are held constant, to avoid compensation caused by other parts of models. The CSM-CROPGRO model in DSSAT already has ET equations for Priestley-Taylor, Penman-FAO-24, Penman-Monteith-FAO-56, and an hourly energy balance approach. In this work, we added transpiration-efficiency modules to DSSAT and AgMaize models and tested the various ET equations against available data on ET, soil water balance, and season-long crop water use of soybean, fababean, maize, and other crops where runoff and deep percolation were known or zero. The different ET modules created considerable differences in predicted ET, growth, and yield.

Avaliação da evapotranspiração na microrregião do Seridó: uma contribuição metodológica

Conselho Nacional de Desenvolvimento Científico e Tecnológico - CNPq