Potassium Behavior with Clay Minerals Composition under Soil Ecosystem: it's Adequacy for Maize Plants
DOI:
https://doi.org/10.47672/aja.911Keywords:
K- behavior, clay mineralogy, physicochemical soil properties, maizeAbstract
Purpose: The target area for the study is one of the agricultural areas of importance in Egypt. It is a suitable area for studying the origin and distribution patterns of clay minerals. Therefore, the focal aims of this study were: (1) to examine the clay minerals' origins in semi-arid regions of Egypt. (2) The behavioral pattern of K in clay minerals in ecological changes, (3) the reflection of K-behavior in soil on the maize plant's nutrient content under soil systems.
Methodology: Evaluation of water samples were: Evaluate the pH and EC, soluble ions, sodium adsorption ratio (SAR), soluble sodium percentage (SSP), sodium to calcium activity ratio (SCAR), residual sodium bicarbonate (RSBC), and residual sodium carbonate (RSC). Also, Evaluation of soil samples were: Evaluate the particle size distribution, OM content, soil pH, Gypsum, CaCO3 content, cation exchange capacity (CEC), exchangeable sodium percentage (ESP), EC, soluble ions, Soil available K, exchangeable K, and total K. Separation of the clay fraction: preparation of soil samples for mineralogical analysis. Qualitative clay mineralogical analysis: X- ray diffactograms were obtained for some selected clay samples using Philips equipment pw (1140/90). Evaluation of plant samples were: Evaluate the N, P, and K concentrations. Statistical analysis: SPSS (v. 20) was used to determine the descriptive statistics and correlation analysis.
Findings: Achieving study aims, a series of methodological steps were implemented to study soil and water properties, and their reflection on maize plants. The irrigation water results analysis showed no problems. The soil properties were also distinguished by the results: common features of this type of soil are a depth of greater than 120 cm, a slightly well-drained clay texture, and poor OM content. The CaCO3 content increases with depth. The available N, P, K were (slight to moderate, very low, and good) respectively. The EC values range from non-saline to moderate saline. As indicated, the X-ray diffraction patterns of the clay fractures are separated from those features. It appears from the analysis that the mineral composition of the clay fracture at both areas is dominated by montmorillonite, kaolinite, and then hydrated mica. Based on the studied soil characteristics, there was a reflection on the maize plant grown, which showed the following: A strong positive correlation between the soluble K content and K in maize plants at the age of 30 days. The multiple correlations were significantly positive between the N and P content available to the grain of maize plants. The results exposed a negative correlation between the available K and K content of maize plants at 45 days of age. Also, there was a significant negative correlation between the exchangeable K and K content in maize plants at 60 days of age.
Contribution to theory, practice and policy: The results presented the significant relationships between the evaluation of the physical and chemical properties of the soil, the content of available nutrients, as well as the type of soil minerals, and their reflections and contributions on the elements contained in the different parts of the maize plants (stems and grains), according to the state of the maize plants age.
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Abdelhafez, A.; Metwalley, S. and Abbas, H. (2020). Irrigation: Water Resources, Types and Common Problems in Egypt. In Technological and Modern Irrigation Environment in Egypt, Best Management Practices and Evaluation; Springer Water: Cham, Switzerland, 2020; pp. 15-34. www.springerprofessional.de
Abdellatif, D.; Abou Kota, M.; Ganzour, Sh. and Allam, A. S. (2021). Soil Spectral Reflectance Behavior Related to Chemical Soil Properties and Macronutrients Using the Plsr Model. International Journal of Agricultural and Statistical Sciences. DocID: https://connectjournals.com/03899.2021.17.309
Abou Kota, M. (2016). Spatial modeling and prediction of soil salinity using SALTMED in a GIS environment in Egypt and Ethiopia. Ph. D. Thesis, Insti. Of African Research and Studies. Cairo Univ. Egypt.
Abou-Kota, M.; Abdellatif, D.; Mahmoud, S. and Kenawy, M. (2021). Modeling of Soil Quality for Assessing Soil Health Using Soil Conditions. Journal of Chinese Soil and Water Conservation, 52 (4): 218-230. https://www.researchgate.net/publication/2753504
Abu-Hashim, M.; Sayed, A.; Zelenakova, M.; Vranayová, Z. and Khalil, M. (2021). Soil Water Erosion Vulnerability and Suitability under Different Irrigation Systems Using Parametric Approach and GIS, Ismailia, Egypt. Sustainability 2021, 13, 1057.https://doi.org/10.3390/su13031057
Abutaha, M.; El-Khouly, A.; Jürgens, N.; Morsy, A. and Oldeland, J. (2019). Elevation- richness pattern of vascular plants in wadis of the arid mountain Gebel Elba, Egypt. African J. of Ecology 57: 238-246. https://doi.org/10.1111/aje.12593
Ahmed, I. (2015). Desertification in Egypt: Current Status and Trends. The Proceedings of the 5th KIDF. https://www.researchgate.net/publication/300484770
Al-Alawi, H.; Ganiyu, A. and Badr, A. (2020). Stabilisation of Sohar's Sabkha soil using waste gypsum plasterboard, IOP Conf. Ser.: Mater. Sci. Eng. 849 012028.
Aldair, de Souza.; Stocio, Malta.; Thiago, Cândido. and Tâmara, Cláudia (2021). Losses and gains of soil organic carbon in grasslands in the Brazilian semi-arid region. Soils and Plant Nutrition. Sci. agric. (Piracicaba, Braz.) 78 (3), 2021. https://doi.org/10.1590/1678-992X-2019-0076
Ali, H.; Ahmed, N. and Abu-Hashim, M. (2020). Potential Effect of Irrigation Intervals and Potassium Phthalate on Fennel Plants Grown in Semi-Arid Regions. Egypt J. Soil. Sci. 2020, 60, 83-98.
Allison, L.; Richards, L.; Reeve, R.; Bernstem, L.; Bower, A.; Brown, J.; Fireman, M.; Hatcher, J.; Hayward, H.; Pearson, G. and Wilcox, L. (1954). Diagnosis and improvement of saline and alkali soils. Untied staff salinity laboratory staff. L.A. Richards (Editor). Agriculture Handbook: 60, USDA. https://www.ars.usda.gov/ARSUserFiles/20360500/hb60_pdf/hb60complete.pdf
APHA (2012). Standard methods for the examination of water and wastewater, 22nd edn. American Public Health Association, American Water Works Association, Water Environment Federation, Washington. http://www.sciepub.com/reference/
Atsuyuki, I. (1983). Potassium Fixation by Clay Minerals during Hydrothermal Treatment. Clays and Clay Minerals, 31(2):81-91.
Berryman, C.; Brower, R.; Charteres, C.; Davis, H.; Davison, R.; Eavis, B. and Yates, R. (1984). Booker tropical soil manual: A handbook for soil survey and agricultural land evaluation in the tropics and subtropics. London: Longman. https://www.tandfonline.com/doi/full/10.1080/23312041.2016.1199523
Bower, C.; Reitemeier, R. and Fireman, M. (1952). Exchangeable cation analysis of saline and alkali soils. Soil Sci. 73:251-261, illus. http://dx.doi.org/10.1097/
Bray, R. and Kurtz, L. (1945). Determination of total organic and Available forms of phosphorus in soils. Soil science 59: p, 39-45. https://doi.org/10.1097/00010694
Brown, G. (1961). X- Ray identification and crystal structures of clay minerals. Mineralogical Soc. Great Britain, Monograph, London.
Buckley, D. and Cranston, R. (1971). Atomic absorption analysis of 18 elements from a single decomposition of aluminosilicate. Chem. Geol., 7, 273-268. http://www1.lasalle.edu/~prushan/Intrumental%20Analysis_files/AA-Perkin%20
Csaba, B.; Arpa, D.; Seyed, M.; Adrienn, S.; Brigitta, T.; Ja´nos, N. and Csaba, L. (2021). Evaluation of the Nutrient Composition of Maize in Different NPK Fertilizer Levels Based on Multivariate Method Analysis. International J. of Agronomy Vol. 2021, ID 5537549, 13 pages https://doi.org/10.1155/2021/5537549
Csaba, B.; Ãrpád, I.; Seyed, M.; Adrienn, S.; Brigitta, T.; János, N. and Csaba, L. (2021). Evaluation of the Nutrient Composition of Maize in Different NPK Fertilizer Levels Based on Multivariate Method Analysis. International Journal of Agronomy, vol. 2021, ID 5537549, 13 p, 2021. https://doi.org/10.1155/2021/55375
Dill, H. (2020). A geological and mineralogical review of clay mineral deposits and phyllosilicate ore guides in Central Europe- A function of geodynamics and climate change. Ore Geol. Rev., 119, 103304. www.researchgate/post/how-can-i-
Diovane, F.; MoterleEdson, C.; BortoluzziJoão, K.; dos Santos R. and Laurent, C. (2019). Does Ferralsol Clay Mineralogy Maintain Potassium Long-Term Supply to Plants?. Rev Bras Cienc Solo 2019;43. https://doi.org/10.1590/18069657rbcs201
Dixon, J. and Weed, B. (1977). Minerals in soil environments. Soil Science Soc. Amer., Madison, Wisconsin, USA.
El-Keblawy, A.; Khedr, A. and Khafaga, T. (2016). Mountainous landscape vegetation and species composition at Wadi Helo: a protected area in Hajar Mountains, UAE. Arid Land Res. and Manag. 30: 389-399. https://doi.org/10.1080
Elnoby, S. and Moustafa, A. (2017). Impact of climate change on the endangered Nubian dragon tree (Dracaena ombet) in the South East. of Egypt. Cat. 16: 25-31.
Emily, F.; Valentino, W.; Stephan, Z.; Lorenz, W.; Frank, H. and Michael, W. (2020). A Critical Evaluation of the Relationship Between the Effective Cation Exchange Capacity and Soil Organic Carbon Content in Swiss Forest Soils. Front. in Forests and Glob. Change. Sep. 2020. Vol. 3, article 98 www.frontiersin.org
FAO. (2019). How to Feed the World in 2050. Available online: http://www.fao.org/fileadmin/templates/wsfs/docs/expert_paper/How_to_Feed_th_World_in_2050.pdf (accessed on 28 November 2019).
Fipps, G. (1998). Irrigation Water Quality Standards and Salinity Management. The Texas A & M University System. http://biochemv.sci.eg
Francis, A.; Christopher, S. and Simon, D. (2020). Assessing Soil Nutrients Variability and Adequacy for the Cultivation of Maize, Cassava, and Sorghum in Selected Agroecological Zones of Cameroon. International Journal of Agronomy Vol. 2020, Art. ID 8887318, 20 p. https://doi.org/10.1155/2020/8887318
Frankenberger, W.; Tabatabai, M.; Adriano, D. and Doner, H. (1996). Bromine, chlorine, and fluorine. In D.L. Sparks et al., Eds. Methods of Soil Analysis, Part 3-Chemical Methods. SSSA Book Series No. 5, SSSA and ASA, Madison, WI, pp. 833-868. http://www.taylorandfrancis.com , http://www.crcpress.com
Gupta, I. (1990). Use of Saline Water in Agriculture: A Study of Arid and Semi-arid Zones of India. New Delhi: Oxford and IBH Publications.
Ibrahiem, N. M.; Abd El Ghani, A. H.; Shawky, S. M.; Ashraf, E. M. and Farouk, M. A. (1993). Measurement of radioactivity levels in soil in the Nile Delta and Middle Egypt. Health Phys. 64 (6), 620-627.
Irakoze, W.; Prodjinoto, H.; Nijimbere, S.; Bizimana, J.; Bigirimana, J.; Rufyikiri, G. and Lutts, S. (2021). NaCl- and Na2SO4-induced salinity differentially affect clay soil chemical properties and yield components of two rice cultivars (Oryza sativa L.) in Burundi. Agronomy, 11, 571. https://doi.org/10.3390/
Jackson, M. (1965). Soil chemical analysis advanced coarse publ. by the Author, Madison, USA.
Jackson, M. (1967). Soil chemical analysis. Prentic Hall, Ladia Private, LTD., New Delhi.
Jackson, M. (1973). Soil Chemical Analysis, p. 46-183, Prentice Hall of India Priv. Ltd., New Delhi.
Jackson, M. (1975). Soil chemical analysis advanced coarse publ. by the Author, Madison, USA.
Jin, L.; Yunus, N.; Hezmi, M.; Rashid, A.; Marto, A.; Kalatehjari, R.; Pakir, F.; Mashros, N. and Ganiyu, A. (2018). Predicting the Effective Depth of Soil Stabilization for Marine Clay Treated by Biomass Silica KSCE, Journal of Civil Engineering, 22, pp. 4316-4326.
John, H. and Ron, H. (2020). Soil Fertility Management for Better Crop Production. Agronomy, 10, 1349; doi:10.3390/agronomy10091349. www.mdpi.com/journal/ag
Jordi, S. and Josep, P. (2021). Potassium Control of Plant Functions: Ecological and Agricultural Implications. Plants, 10, 419. https://doi.org/10.3390/plants10020419.
Knudsen, D.; Peterson, G. and Pratt, P. (1982). Lithium, sodium and potassium. In Methods of Soil Analysis, Part 2, Ed. A.L. Page, p. 225-246, Am. Soc. Agron. Inst. Pub! Madison, WI. https://www.waterboards.ca.gov/waterrights/water_issues/
Kralj, D. and Vdović N. (2000). The influence of some naturally occurring minerals on the precipitation of calcium carbonate polymorphs. Water Res., 34, pp. 179-184
Lam, V. and Tran, Th. (2021). The effects of salinity on changes in characteristics of soils collected in a saline region of the Mekong Delta, Vietnam. Pub by De Gruyter Open Access on April 20, 2021. http://doi.org/10.1515/chem-2021-003.
Li Yang, Y. Yu Feng, W.; Muhammad, Z. and Xun, B. (2021). Gradual Application of Potassium Fertilizer Elevated the Sugar Conversion Mechanism and Yield of Waxy and Sweet Fresh-Eaten Maize in the Semiarid Cold Region. Journal of Food Quality, Vol. 2021, 11 pages. https://doi.org/10.1155/2021/6611124
Lisuma, J.; Mbega, E. and Ndakidemi, P. (2020). Influence of Tobacco Plant on Macronutrient Levels in Sandy Soils. Agro, 10, 418. https://doi.org/10.3390/agro
Liu, Z.; Zhang, Z.; Wang, Z.; Jin, B.; Li, D.; Tang, R. and De Yoreo, J. (2020). Shape preserving amorphous to crystalline transformation of CaCO3 revealed by in situ TEM. Proc. Natl. Acad. Sci. USA, 117, pp. 3397-3404
Liu, D.; Xu, Y.; Papineau, D.; Yu, N.; Fan, Q.; Qiu, X. and Wang H. (2019). Experimental evidence for abiotic formation of low- temperature proto dolomite facilitated by clay minerals. Geochim. Cosmochim. Acta, 247, pp. 83-95
Maged, M.; Ahmed, A.; Norbert, J. and Jens, O. (2020). Plant communities and their environmental drivers on an arid mountain, Gebel Elba, Egypt. Vegetation Classification and Survey 1: 21-36. http://doi.org//10.3897/vcs/2020/38644
Mahmoud, S.; Abou Kota, M.; Ganzour, Sh. and Abdellatif, D. (2020). Mathematical modeling of water quality with a different chemical state; nutrients and arid environmental conditions, Siwa oasis, Egypt. European Journal of Physical Science, vol. 3, issue, 1. pp 15-36. www.ajpojournals.org
Mehra, O. and Jackson, M. (1960). Iron oxide removal from soil and clay by a dithionite- citrate system buffered with bicarbonate. Clay and Clay Minerals, 7: 317-327.
Melo, V. F.; Singh, B.; Schaefer, C. E.; Novais, R. F. and Fontes, M. P. (2001). Chemical and Mineralogical Properties of Kaolinite-Rich Brazilian Soils. Soil Science Society of America Journal, Volume 65, Issue 4, Pages: 1027-1350.
Moataz, Kh. And Ahmed, G. (2018). Assessment of Heavy Metals Contamination in Agricultural Soil of Southwestern Nile Delta, Egypt. Soil and Sediment Contamination: An International Journal, 27:7, 619-642.
Moterle. D.; Kaminski, J.; Rheinheimer, D.; Caner, L. and Bortoluzzi, E. (2016). Impact of potassium fertilization and potassium uptake by plants on soil clay mineral assemblage in South Brazil. Plant Soil; 406:157-72. https://doi.org/10.100
Muhammad, A. (2020). Role of Potassium in Maize Production: A Review. Op Acc J Bio Sci & Res 3(5).
Nabeel, K.; Harith, E.; Abideen, A. and Muyideen, O. (2021). Durability of clayey soil stabilized with Potassium additive. IOP Conf. Series: Materials Science and Engineering 1144 (2021). doi:10.1088/1757-899X/1144/1/012092
Nurhanan, A. and Wan, I. (2014). Nutritional compositions and antioxidative capacity of the silk obtained from immature and mature corn. Journal of King Saud University - Science, Vol. 26, Issue 2, P 119-127. https://doi.org/10.1016/j.jksus
Page, A.; Miller, R. and Keeney, D. (1982). Methods of soil analysis. Part 2. Chemical and Microbiological Properties. 2nd (Ed.). Amer. Soc. of Agronomy. Madison, Wisconsin, USA. https://doi.org/10.1002/jpln.19851480319
Paola, A.; Pierre, B.; Vincenza, C.; Vincenzo, D. and Bruce, V. (2016). Short term clay mineral release and re-capture of potassium in a Zea mays field experiment. Geoderma; 264:54-60. https://doi.org/10.1016/j
Paolo, F. (2020). Clay Minerals in Hydrothermal Systems. Minerals 2020, 10, 919; doi:10.3390/min10100919 www.mdpi.com/journal/minerals
Pellegrino, E.; Piazza, G.; Arduini, I. and Ercoli, L. (2020). Field Inoculation of Bread Wheat with Rhizophagus irregularis under Organic Farming: Variability in Growth Response and Nutritional Uptake of Eleven Old Genotypes and a Modern Variety. Agronomy 2020, 10, 333. https://doi.org/10.3390/agronomy10030333
Pierre, B.; Christophe M.; Claire, Ch.; Luc, A. and Bruce, V. (2008). Clay minerals as a soil potassium reservoir: observation and quantification through X-ray diffraction. Plant Soil (2008) 302:213-220.
Piper, C. (1944). Soil and Plant Analysis. New York: Interscience.
Piper, C. (1950). Soil and Plant Analysis. Inter. Sci. Publisher, Inc., New York, USA.
Rakotondrabe, F.; Ngoupayou, J.; Mfonka, Z.; Rasolomanana, H.; Abolo, N. and Ako, A. (2018). Water quality assessment in the Btar-Oya gold mining area( East-Cameroon): multivariate statistical analysis approach. Sci Total Environ 610-611:831-844. https://doi.org/10.1016/j.scitotenv.2017
Rhoades, J. (1982). Cation exchange capacity. In Methods of soil analysis, part 2: Chemical and microbiological properties, 2nd ed., ed. A. L. Page et al., 149-157. Madison, Wisc. : ASA. https://doi.org/10.2134/agronmonogr9.2.2ed.c8
Richard, J.; Hanadi, E. and Tubeileh, A. (2006). Soil System Management Under Arid and Semi-Arid Conditions. In book: Biological Approaches to Sustainable Soil Systems (pp.41-55), Edition: First, Chapter: 4, Publisher: CRC Press, Editors: Norman Uphoff.
Santana, M.; Sampaio, E.; Giongo, V.; Menezes, R.; Jesus, K.; Albuquerque, E.; Nascimento, D.; Pareyn, F.; Cunha, T.; Sampaio, R. and Primo, D. (2019). Canbon and nitrogen stocks of soils under different land uses in Pernambuco state, Brazil. Geoderma Regional 15: e00205.
Sardans, J. and Peñuelas, J. (2015). Potassium: a neglected nutrient in global change. Global Ecol Biogeogr; 24:261-75. https://doi.org/10.1111/geb.12259
Schoonover, W. (1952). Examination of soils for alkali extension service. University of California, Berkeley, California (Mimeographed).
Soltanpour, P. and Workman, S. (1985). Modification of the NH4 HCO3-DTPA soil test to omit carbon black. Commun. Soil Sci. Plant Anal. 10, 1411-1420.
SPSS, (2015). Command syntax reference. Chicago. Illinois: SPSS 20.0 Inc. 2015.
Stuart, P.; Toby, O. and Randal, S. (2011). Potassium Fixation and Its Significance for California Crop Production. Crops,Vol. 95, 2011, No. 4; pp 16-18.
Tilman, E.; Tilman, D.; Crawley, M. and Johnston, A. (1999). Biological weed control via nutrient competition: potassium limitation of dandelions. Ecol Appl 9:103-111. https://www.researchgate.net/publication/225313579
Todd, D. (1980). Ground Water Hydrology. Wiley, New York, USA.
USDA. (1954). Diagnosis and Improvement of Saline and Alkali Soils. Agriculture Handbook 60, US Gov. Printing Office, Washington, DC, USA.
Van Reeuwijk, L. (1993). Procedures for Soil Analysis. CIP- Gegevens Koninklijke Bibliotheek, Den Haag, Wageningen: International Soil Reference and Information Centre. Technical Paper/ International Soil Reference and Information Centre. ISSN 0923-3792: No. 9. Trefw.: Bodemkunde. ISRIC. Fourth Edition.
Weil, R. and Brady, N. (2016). Nature and Properties of Soils, the: Pearson New International Edition. London: Pearson Higher Ed.
Wright, C. (1939). Soil Analysis. Thomas Murby Co., London.
Zhang, M.; Li, X.; Wang, H. and Huang, Q. (2018). Comprehensive analysis of grazing intensity impacts soil organic carbon: a case study in typical steppe of Inner Mongolia, China. Applied Soil Ecology 129: 1-12.
Zinabu, W. (2016). A Review on Evaluation of Soil Potassium Status and Crop Response to Potassium Fertilization. Journal of Environment and Earth (Online) Vol.6, No.8, 2016. www.iiste.org
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