تعیین نیاز آبی و ضرایب گیاهی یک جزئی و دوجزئی گیاه زعفران (.crocus sativus l) در سال اول پژوهش

استفاده‌ بهینه و صحیح از منابع آب، نیازمند محاسبه میزان آب مصرفی و تعیین ضرایب گیاهی متناسب با هر منطقه است. این تحقیق به منظور تعیین تبخیر – تعرق و ضرایب گیاهی گیاه زعفران و تبخیر – تعرق گیاه مرجع چمن به دو روش لایسیمتری و فائو – پنمن - مانتیث در منطقه نیمه خشک بیرجند و در سال زراعی 1399-1398 صورت گرفته است. بدین منظور گیاه زعفران در شش لایسیمتر و گیاه مرجع چمن در سه لایسیمتر، در مجموعه آزمایشگاه های لایسیمتری دانشکده کشاورزی دانشگاه بیرجند، کشت شد. دوره رشد گیاه زعفران به چهار مرحله ابتدایی (27 روز)، توسعه (54 روز)، میانی (40 روز) و نهایی(54 روز) تقسیم شد. میانگین تبخیر – تعرق گیاه مرجع چمن به روش های لایسمتری و فائو – پنمن – مانتیث به ترتیب برابر 4/32 و 4/19 میلی متر بر روز و میانگین تبخیر – تعرق گیاه زعفران در دوره 175 روزه رشد، برابر با 2/34 میلی متر بر روز بدست آمد. مقدار میانگین ضرایب گیاهی یک جزئی به ترتیب برابر با 0/36، 0/66، 0/86 و 0/42 و میانگین ضرایب گیاهی دوجزئی به ترتیب برابر با 0/37، 0/67، 0/87 و 0/42، در طول مراحل مختلف رشد برآورد شد.

determination of single and dual crop coefficients of saffron (crocus sativus l.) in the first year of research

introduction: water is one of the most common and at the same time the most important substance on the planet. all kinds of plants in different parts of the earth need more water than any other environmental factor. the main purpose of direct measurements or evapotranspiration calculations is the amount of water required by plants. knowledge of the water need of plants in each region and its use in agricultural planning plays an important role in water usage. due to the reduction of fresh water reserves in the world, accurate estimation of evaporation and transpiration and water requirement of plants seems to be important. therefore, developing an irrigation plan and applying proper irrigation management can reduce the losses caused by water resources. the aim of the current research is to determine the evapotranspiration and plant coefficients of saffron plant and the evapotranspiration of the grass reference plant by two methods, lysimeter and fao-penman-mantith, in birjand city. materials and methods: the research was carried out in the agricultural year of 2018-2019 in the lysimetry laboratory of the faculty of agriculture, birjand city, for this purpose. the saffron plant was grown in six lysimeters and the grass reference plant in three lysimeters, in the collection of lysimetry laboratories of the faculty of agriculture, birjand university. the growth period of saffron plant was divided into four initial (27 days), development (54 days), middle (40 days) and final (54 days) stages. irrigation was done daily until the soil moisture reached the agricultural capacity. the irrigation volume was adjusted based on the soil moisture level, the reason for which was mentioned above. the start time of irrigation was determined based on soil moisture and fc. the end of irrigation was done according to the condition and moisture content of the soil.results and discussion: the average of evapotranspiration of the grass reference plant by lysimetric and fao-penman-monteith methods was obtained equal to 4.32 and 4.19 mm/day, respectively, and the average of evapotranspiration of the saffron plant during the 175-day growth period was obtained equal to 2.34 mm/day. during different stages of growth, the amount of the average of single crop coefficient was estimated 0.36, 0.66, 0.86 and 0.42, respectively, and the average of dual crop coefficient was estimated 0.37, 0.67, 0.87 and 0.42, respectively. with the passage of time, the amount of evaporation-transpiration of the reference plant has increased, which can be attributed to the long day length and the increase in net solar radiation, with the increase in temperature, the amount of evaporation-transpiration also has increased, so the demand of the plant to receive water increases.conclusion: observations indicated that at the beginning of the period, due to high evaporation, this coefficient was clearly obtained from their sum, but in the middle stage, due to the decrease in evaporation and the predominance of transpiration, the coefficient of vegetation in most cases was sweating has approached and this trend of changes has been the same in all lysimeters. the value of the basic vegetation coefficient (transpiration component) gradually increased after passing through the initial stage and reached the maximum value in the middle stage. the value of the evaporation coefficient from the soil surface (ke) is the highest after the surface soil layer is wetted by rain or irrigation. as this layer dries, the evaporation coefficient will increase. in the condition that there is no water left in the surface layer of the surface soil, the evaporation coefficient reaches zero. the two-component vegetation coefficient, which is the sum of the transpiration and evaporation components, also decreases gradually. the fluctuations seen in the graph are due to the short irrigation period.