ВЛИЯНИЕ МИНЕРАЛЬНЫХ УДОБРЕНИЙ И ГИББЕРЕЛЛИНОВ НА РОСТ, РАЗВИТИЕ И УРОЖАЙНОСТЬ ФАСОЛИ (PHASEOLUS VULGARIS L.), ВЫРАЩИВАЕМОЙ В ПРОВИНЦИИ КАПИСА, АФГАНИСТАН

The common bean (Phaseolus vulgaris L.) is an essential legume widely utilized for human consumption. Renowned for its great protein content, pulses serve as an excellent dietary source, offering a blend of carbohydrates, nutritional fiber, and necessary minerals, as noted by nutritionists. While the health benefits and nutritional worth of legumes are well established

In Afghanistan, legumes are careful the primary sources of dietary protein, with common bean (Phaseolus vulgaris L.), chickpeas (Cicer arietinum), peas (Pisum sativum), lentils (Lens culinaris), mung beans (Vigna radiata), and faba beans (Vicia faba) being commonly consumed. Due to the prevalent cultivation of various plants throughout the country, the usage of fertilizers remains minimal, effective and applicable rates take yet to be established, and outdated agricultural practices continue to be employed.

The experience objectives identify to the most effective combinations and concentrations fertilizer and phytohormone that promote optimal development and harvest of beans in the northeastern region of Afghanistan, specifically in Kapisa province.

This research was performed at the Crop Research site of Alberoni University, Kapisa, Afghanistan, from 2022 to 2024. It is located at a latitude of 35.0439 and a longitude of 69.2748, approximately 1500 m overhead marine level. The yearly precipitation is around 400 mm, with most rainfall occurring during the winter and spring periods, while summer temperatures fluctuate between 25 to 40 °C. The data on rainfall, along with maximum, minimum, and average heats due to the study period, are illustrated in Fig 1 and Fig 2.

Figure 1 - Agrometeorological data when conducting experiments on the region of Alberoni University, Kapisa, Afghanistan in 2022–2024

DOI:10.60797/JAE.2025.56.4.1

Figure 2 - Agrometeorological data when conducting experiments on the region of Alberoni University, Kapisa, Afghanistan in 2022–2024

DOI:10.60797/JAE.2025.56.4.2

The agrochemical analysis of the soil was done at the Russian State Agrarian University – Moscow Timiryazev Agricultural Academy, revealing that the soil exhibited a relatively alkaline reaction (initial pH = 8.10, post-cultivation pH = 8.52). The soil was identified as having low organic matter content, with humus levels decreasing from 1.95% to 1.75% after cultivation. Additionally, it was found to have low levels of available nitrogen, dropping from 0.10% to 0.07% following the cultivation period. The availability of phosphorus (P2O5) was also low, with values decreasing from 13.55 mg/kg to 12.32 mg/kg after cultivation. Similarly, the potassium content (K2O) was low, showing a reduction from 96.33 mg/kg to 90.5 mg/kg after the growing season, as summarized in Table 1.

The research was structured using a complete randomized block design, comprising a total of sixteen treatments, including a control, and replicated three times. The specific treatment combinations are outlined in Table 2, which details the investigational arrangement. In this seeking selected variety was Rosecoco (GPL2). Data evaluation was conducted using the OPSTATS online software for statistical analysis.

3.1. Plant height

The analysis of plant height in relation to numerous use of NPK and G is summarized in Table 3. It shown that the common bean plants exhibited a significant increase in height due to the diverse measures of these NPK and G applied. Both NPK and G treatments had a pronounced influence on plant height when over to the control. The tallest plants, reaching a height of 100.5 cm, were achieved by application of A13. In contrast, the control exhibited the shortest plant height (68.5 cm), aligning with the observations made by Singh et al. in 2014

3.2. Dry matter plant

The data regarding the dry mass of beans affected by dissimilar levels of NPK and G are compiled in Table 3.

The dry mass of bean plants showed a significant increase when unlike levels of NPK and G were applied. The outcomes indicated that the use of these nutrients had a profound impression on the dry weight of the plants, equated to the control and other treatments. The peak dry mass reached was 7.1 grams, achieved with A13, This results statistically similar with A8, A9, A11, A12, A14, A15 and A16. In contrast, the control exhibited the lowest dry mass at 3.5 grams, corroborating findings by Meseret and Mohammed in 2014

3.3. Number of pods plant

The use of varying rates of NPK and G had a significant effect on the numeral of pods produced per plant, as illustrated in Table 4. The all-out number of pods per plant was recorded at 11.8, subsequent from the combination of A12, excepting control, A2, A6, A14 and A15 it was at par with rest treatments. Conversely, the control showed the least number of pods per plant at 6.3. It is noteworthy that fewer pods were observed on the lower branches, paralleled to the upper sections of the main stem. This observation is consistent with the findings reported by Tuarira and Moses in 2014

3.4. Number of seed per plant

The use of NPK and G led to a notable increase in the number of seeds produced per plant, as illustrated in Table 4. The higher count of seeds per plant (64.7) was achieved with the treatment comprising A11, which was similar with A8, A9, A11 and A12. Each of the applied NPK and G treatments resulted in a major rise in seed count compared to the control. In contrast, the control recorded the lowest seed count (26.4). These results corroborate the findings of Vemulakonda, et al., 2024

3.5. 1000 seed weight

The study revealed a notable impact on the 1000 seed weight measurements. The combination treatment A11 resulted in the highest 1000-seed weight of 317g, except A12, A13 better than other treatments. Conversely, the control demonstrated the lowest weight, measuring 231.7g, leading to a significant difference of 85.3g, as detailed in Table 4 and illustrated in Fig 3. These results align with the findings documented by Abdel Latif Y Idris in 2008

3.6. Seed yield

The data analysis indicates that the application of NPK fertilizers and G had a significant impact on the seed yield of beans, during the period of 2022–24, as shown in Table 4 and Fig 3. Furthermore, the maximum seed yield (2 t/ha) was noted from the A13, which was statistically obviously better than all other treatments. Conversely, the lowest seed yield (0.9 t/ha) was recorded in the control. The application of NPK, and G resulted in beneficial effects on yield and improved yield characteristics, with the most significant increases observed at higher levels of these nutrients. Similar outcomes were reported by Vemulakonda, et al., in 2024

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Figure 3 - The productivities of seed yield by ton per hectare and weight of 1000 seeds counted with gram during field seasons 2022-2024

DOI:10.60797/JAE.2025.56.4.7

3.7. 1000 seed weight

The research exhibited a significant effect of the data on 1000 seed weight. The treatment of N at 60 kg/ha, P at 60 kg/ha, K at 30 kg/ha + GA at 100 ppm recorded the maximum seed weight of 317g. In contrast, the control treatment showed the minimum weight of 231.7 g per 1000 seeds, resulting in a difference of 85.3g, which is the data related to 1000 seed weight inserted in Table 4 and Fig 3. These findings are consistent with the results reported by Abdel Latif Y Idris in 2008

It turned up significant enhancements in growth and yield through specific nutrient combinations, particularly a mixture of A13, which led to the best results. The findings point out the importance of managing nutrients and growth regulators to boost bean production, suggesting that the right combinations can enhance agricultural outputs. These results are promising for Afghan bean farmers, as they could improve crop performance and profitability. Future studies should focus on finding the best nutrient mixes for different bean varieties and soil conditions to optimize farming practices.