Phosphoric regime of light chestnut soil and sugar beet yield with long-term use of phosphorous fertilizers

• Autorzy: Alimbekova Balnur , Yeleshev Rakhimzhan , Bakenova Zhenisgul , Shibikeyeva Aigerim , Balkozha Marzhan

Identyfikatory

DOI

10.24425/jwld.2021.137107

• Języki publikacji: EN

Abstrakty

EN

This study presents the results of research on the effect of long-term use of phosphorus fertilizers on permanent sugar beet crops for more than 50 years and on the transformation of phosphate forms on light chestnut soil and its yield. Our work aims to establish the main factors of quantitative and qualitative changes in various phosphates in light chestnut soil. Despite the large amount of practical material, the influence duration of phosphorus fertilizer application has not been sufficiently studied on the irrigated soils of Kazakhstan. It should be noted that the current study was carried out in long-term stationary experimental sites for the production of sugar beet with permanent sowing. The introduction of phosphate fertilizers primarily on the permanent crops of sugar beets in the same norms contributes to a more significant increase in gross phosphorus reserves. The soil content of gross phosphorus for 58 years on the control and nitrogen-potassium variants show practically no changes. Furthermore, when phosphorus fertilizers are applied on the variant with the annual application of a single norm of phosphorus and its amount for 58 years (4400 kg∙ha^–1 of application doses) its content increased by 2660 mg∙kg^–1, and with the introduction of its one and a half norms (6600 kg of application doses) by 2860 mg∙kg^–1 of soil.

Słowa kluczowe

EN

ammonia nitrogen; chestnut soil; fertilization; gross phosphorus; mineral nitrogen; mineral phosphorus; mobile phosphorus; organic phosphorus; permanent sugar beet crop

• Wydawca: Wydawnictwo ITP
• Czasopismo: Journal of Water and Land Development
• Rocznik: 2021
• Tom: no. 49
• Strony: 151--155
• Opis fizyczny: Bibliogr. 21 poz., tab.

Twórcy

autor

Alimbekova Balnur

• Kazakh National Agrarian University, Faculty of Agronomy, Abay avenue 8, Almaty 050010, Kazakhstan

• https://orcid.org/0000-0002-0989-9281

autor

Yeleshev Rakhimzhan

• Kazakh National Agrarian University, Faculty of Agronomy, Abay avenue 8, Almaty 050010, Kazakhstan
• National Academy of Sciences of the Republic of Kazakhstan, Almaty, Kazakhstan

• https://orcid.org/0000-0001-9310-3532

autor

Bakenova Zhenisgul

• Kazakh National Agrarian University, Faculty of Agronomy, Abay avenue 8, Almaty 050010, Kazakhstan

• https://orcid.org/0000-0002-0766-7006

autor

Shibikeyeva Aigerim

• Kazakh National Agrarian University, Faculty of Agronomy, Abay avenue 8, Almaty 050010, Kazakhstan

• https://orcid.org/0000-0003-2085-2027

autor

Balkozha Marzhan

• Kazakh National Agrarian University, Faculty of Agronomy, Abay avenue 8, Almaty 050010, Kazakhstan

• https://orcid.org/0000-0002-3746-9887

Bibliografia

• BASIBEKOV B.S., TORCHINA O.B. 1978. Balans fosfora v sveklovichnom sevooborote na svetlo-kashtanovoy pochve Yugo-Vostoka Kazakhstana [Phosphorus balance in beet crop rotation on light chestnut soil in South-East Kazakhstan]. Agrokhimiya. No. 8 p. 17–21.
• BURZYŃSKA I. 2019. Monitoring of selected fertilizer nutrients in surface waters and soils of agricultural land in the river valley in Central Poland. Journal of Water and Land Development. No. 43 p. 41–48. DOI 10.2478/jwld-2019-0061.
• CHEN L., XUN W., SUN L., ZHANG N., SHEN Q., ZHANG R. 2014. Effect of different long-term fertilization regimes on the viral community in an agricultural soil of Southern China. European Journal of Soil Biology. Vol. 62 p. 121–126. DOI 10.1016/j.ejsobi.2014.03.006
• ELESHEV R.E., BAKENOVA Z.B. 2012. Changes in the biological activity of chestnut soils upon the long-term application of fertilizers in a rotation with oil-bearing crops. Eurasian Soil Science. Vol. 45(11) p. 1081–1085. DOI 10.1134/S10642293 1211004X.
• FARMER A.M. 2018. Phosphate pollution: A global overview of the problem. In: Phosphorus: Polluter and resource of the future – Removal and recovery from wastewater. Ed. C. Schaum. IWA Publishing p. 28–53. DOI 10.2166/9781780408361_035.
• GINZBURG K.E. 1981. Fosfor v osnovnykh tipakh pochv SSSR [Phosphorus in the of the USSR]. Moscow. Nauka pp. 242.
• GINZBURG K.E., LEBEDEVA L.S. 1971. Metodika opredeleniya mineralnyh form fosfatov v pochvakh [Determination of mineral phosphorus compounds in soils]. Agrohimiya. No. 1 p. 25–34.
• GUREEV I.I. 2011. Sovremennyye tekhnologii vozdelyvaniya i uborki sakharnoy svekly: prakticheskoye rukovodstvo [Modern technologies of cultivation and harvesting of sugar beet: Practical guide]. Мoscow. Pechatnyi gorod. ISBN 5984670089 pp. 256.
• JONER E.J. 2000. The effect of long-term fertilization with organic or inorganic fertilizers on mycorrhiza-mediated phosphorus uptake in subterranean clover. Biology and Fertility of Soils. Vol. 32(5) p. 435–440. DOI 10.1007/s003740000279.
• MACHIGIN B.P. 1940. Sravnitel'noye issledovaniye metodov opredeleniya dostupnykh fosfatov v karbonatnykh pochvakh Sredney Azii [Comparative study of the methods for determining available phosphates in the carbonate soils of Central Asia]. Pochvovedeniye. No. 11 p. 12–23.
• MAHFOUD Z., KHALDI A., KORICHI K. 2020. Wastewater reuse and mapping of irrigable soils: Case of Sidi Bel Abbes City, Algeria. Journal of Water and Land Development. No. 46. DOI 10.24425/jwld.2020.134208.
• MENEZES-BLACKBURN D., GILES C., DARCH T., GEORGE T.S., BLACKWELL M., STUTTER M., BROWN L. 2018. Opportunities for mobilizing recalcitrant phosphorus from agricultural soils: A review. Plant and Soil. Vol. 427(1–2) p. 5–16. DOI 10.1007/s11104-017-3362-2.
• MUKHINA S.V., SUPRUN S.V., BALYUNOVA E.A. 2010. Vliyaniye agrohimicheskih faktorov na produktivnost’ [Influence of agrochemical factors on productivity]. Sakharnaya Svekla. No. 6 p. 18–23.
• NOSKO B. 2017. Modern problems of phosphorus in farming agriculture and ways of their solution. Bulletin of Agricultural Science. Vol. 6 p. 5–12. DOI 10.31073/agrovisnyk201706-01.
• PLATTS M.J., LEONG Y.Y. 2020. Soil fertility is a productive capital asset. Agricultural Sciences. Vol. 11(8) p. 744–776. DOI 10.4236/as.2020.118049.
• SHIBIKEYEVA A.M., YELESHEV R.Y., KALDYBAYEV S., MALIMBAYEVA A.D. 2015. Influence of long-term use of phosphate fertilizers on accumulation of various forms of phosphates in brown soils and influence of levels of available phosphates on crop yield in crop rotation. Biosciences Biotechnology Research Asia. Vol. 12(1) p. 111–118.
• SMIT A.L., BINDRABAN P.S., SCHRÖDER J.J., CONIJN J.G., VAN DER MEER H.G. 2009. Phosphorus in agriculture: global resources, trends and developments: Report to the Steering Committee Technology Assessment of the Ministry of Agriculture, Nature and Food Quality, The Netherlands, and in collaboration with the Nutrient Flow Task Group (NFTG), supported by DPRN (Development Policy review Network) [online]. Report No. 282. Wageningen. Plant Research International pp. 36. [Access 12.03.2020]. Available at: https://edepot.wur.nl/12571
• STAMENKOVSKA I.J., STOJCHESKA A.M., MARKOSKI M., ZGAJNAR J. 2019. Assessing the influence of soil properties on optimal production structure at vegetable farms. Contributions. Section of Natural, Mathematical & Biotechnical Sciences. Vol. 40(2) p. 18–29.
• TIRADO R., ALLSOPP M. 2012. Phosphorus in agriculture: Problems and solutions. Greenpeace Research Laboratories Technical Report. Review. Vol. 2 pp. 35.
• YELESHEV R.E., IVANOV A.L. 1987. K voprosu ob optimizacii fosfatnogo rezhima pochv. V: Sbornik dokladov. Parametry plodorodiya osnovnyh tipov pochv [On the question of optimizing the phosphate regime of soils. In: Collection of reports. Fertility parameters of the main soil types]. Moscow p. 159–166.
• XIN X., ZHANG X., CHU W., MAO J., YANG W., ZHU A., ZHONG X. 2019. Characterization of fluvo-aquic soil phosphorus affected by long-term fertilization using solution 31P NMR spectroscopy. Science of the Total Environment. Vol. 692 p. 89–97. DOI 10.1016/j.scitotenv.2019.07.221.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).