POLLUTION CONTROL AND PESTICIDES
Ключевые слова:
Key words: slow release fertilizer, carbamideformaldehyde fertilizers (CFI),Artemisia leucodes Schrenk - wormwood whitish, denitrification, ureaformaldehyde fertilizer (IFIs), Standard tuki, yield, budization.Аннотация
Abstract: When making CFF nitrogen consumption of soil resources in the year
of its operation increases in the second year (aftereffects) decreases unproductive
nitrogen losses from CFF markedly lower than urea. CFF raises productivity
Artemisia leucodes Schrenk. In field experiments, conducted in the irrigated typical
gray soils and debris, the harvest was bigger by 10-30% compared to the control. The
research results point to a definite advantage of using a slow acting carbamide-
formaldehyde fertilizers (CFF) than urea and ammonium nitrate in reducing
environmental pollution harmful to the body remains of the fat
It was found that the use of slow acting . Urea-formaldehyde fertilizer is
particularly important in conditions of saline soils with shallow groundwater where
significant nitrogen losses occur as a result of leaching of nitrates into the
groundwater.
It was revealed that a higher content of nitrates in the soil when making nitrogen
fertilizer as ammonium nitrate and urea lead to a significant loss of battery sizes that
reach considerable values. As a result, there are a number of issues surrounding
pollution as the most dangerous are increasingly finding the nitrates in the soil. It
should be noted that not only accumulate nitrate in the soil - soil, ground water, but
higher than allowable standards accumulate in food and feed, thus enters the body of
animals and humans
Библиографические ссылки
List of literature:
1. Rajan, M., Shahena, S., Chandran, V., & Mathew, L. (2021). Controlled release of
fertilizers—concept, reality, and mechanism. In Controlled release fertilizers for
sustainable agriculture (pp. 41-56). Academic Press.
2. Fazelian, N., & Yousefzadi, M. (2022). Nano-biofertilizers for enhanced nutrient
use efficiency. In Nano-enabled Agrochemicals in Agriculture (pp. 145-158).
Academic Press.
3. Guaya, D., Hermassi, M., Valderrama, C., Farran, A., & Cortina, J. L. (2016).
Recovery of ammonium and phosphate from treated urban wastewater by using
potassium clinoptilolite impregnated hydrated metal oxides as NPK
fertilizer. Journal of Environmental Chemical Engineering, 4(3), 3519-3526.
4. Cheng, H., Zhu, X., Sun, R., Niu, Y., Yu, Q., Shen, Y., & Li, S. (2020). Effects of
different mulching and fertilization on phosphorus transformation in upland
farmland. Journal of environmental management, 253, 109717.
5. Barragán-Ocaña, A., Silva-Borjas, P., & Olmos-Peña, S. (2022). Scientific and
technological trajectories for sustainable agricultural solutions: the case of
biopesticides. In Biopesticides (pp. 93-105). Woodhead Publishing.
6. Hou, J., Liu, W., Wang, B., Wang, Q., Luo, Y., & Franks, A. E. (2015). PGPR enhanced phytoremediation of petroleum contaminated soil and rhizosphere
microbial community response. Chemosphere, 138, 592-598.
7. Gao, D., Zhao, H., Wang, L., Li, Y., Tang, T., Bai, Y., & Liang, H. (2022). Current
and emerging trends in bioaugmentation of organic contaminated soils: A
review. Journal of Environmental Management, 320, 115799.
8. Yuan, M., Zhu, X., Sun, H., Song, J., Li, C., Shen, Y., & Li, S. (2023). The addition
of biochar and nitrogen alters the microbial community and their cooccurrence
network by affecting soil properties. Chemosphere, 312, 137101.
9. Kuandykova, M., Akpanov, A., Tleubayeva, S., Belgibayev, A., Makhmudov, A.,
& Atchabarova, A. (2023). Attracting Investment for Rural Development:
Introduction of Organic Agriculture and ESG Principles in Kazakhstan. Journal of
Environmental Management and Tourism, 14(5), 2196-2206.
10. De, L. C., De, T., Biswas, S. S., & Kalaivanan, N. S. (2021). Organic plant nutrient,
protection and production management. In Advances in Organic Farming (pp. 115-
131). Woodhead Publishing.
11. Worrall, F., Spencer, E., & Burt, T. P. (2009). The effectiveness of nitrate
vulnerable zones for limiting surface water nitrate concentrations. Journal of
Hydrology, 370(1-4), 21-28.
12. Medina, R., Fernandez-Gonzalez, A. J., Garcia-Rodriguez, F. M., Villadas, P. J.,
Rosso, J. A., Fernández-López, M., & Del Panno, M. T. (2020). Exploring the effect
of composting technologies on the recovery of hydrocarbon contaminated soil post
chemical oxidative treatment. Applied Soil Ecology, 150, 103459.