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Status of Selected Physicochemical Properties of Soils Under Long Term Sugarcane Cultivation Fields at Wonji-Shoa Sugar Estate

Tesfaye Wakgari
Published in American Journal of Agriculture and Forestry (Volume 9, Issue 6)
Received: 25 September 2021    Accepted: 17 November 2021    Published: 25 November 2021
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Abstract

A declining trend in per hectare yield of sugarcane in Wonji-Shoa Sugar Estate is being observed due to altering of soil physicochemical properties resulted from long term sugarcane cultivation. Cognizant of this fact, a study was conducted in 2017at Wonji-Shoa Sugar Estate with the objective of determining the effects of more than 62 years of sugarcane cultivation on the physicochemical properties of soil. In order to achieve this objective disturbed and undisturbed soil samples were collected from 0-30 and 30-60 cm layers of selected cultivated and uncultivated light and heavy soils for laboratory analysis. Results of the study indicated that long term cultivation of sugarcane at the same depth and low soil organic matter content of cultivated fields induced soil compaction and consequently highest bulk density was recorded in subsoil layer of cultivated than uncultivated land. The bulk density and total porosity values were out of ranges recommended for optimum sugarcane cultivation and suggest the existence of some degree of compaction. The finding further showed that the pH of study area soils is out of the normal pH range for sugarcane plant growth. The soil organic carbon, total nitrogen content and available phosphorus concentration of soils under both land uses of all soils was found within low range. Therefore, based on the result of the study it can be concluded that under condition of strong base soil pH of study area the availability of essential nutrients are critically affected. This indicates that the strong pH values at Wonji-Shoa Estate require more attention. Moreover, the low levels of organic carbon, total nitrogen, and available P contents under both cultivated and uncultivated soils indicated that soil fertility is among the constraints for sustainable sugarcane production in the estate. Based on the findings and conclusions of this study one can recommend that to maintain sustainability of sugarcane production in the estate soil management practices that can protect as well as ameliorate soil compaction, increase soil organic carbon, total nitrogen, soil available P and that can decrease soil pH are important. Nevertheless, in order to give conclusive recommendation further research studies are needed for more soil management units in the estate.

Published in American Journal of Agriculture and Forestry (Volume 9, Issue 6)
DOI 10.11648/j.ajaf.20210906.19
Page(s) 397-408
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

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Keywords

Soil Physicochemical Properties, Sugarcane, Long Term Cultivation, Land Use

References
[1] Kodesova, H. 2011. Role of physicochemical properties in soil quality. Chemistry Science Reviews Letters. 4: 57–66.
[2] Tesfaye, W., Kibebew, K., Bobe, B., Melesse, T and Teklu, E., 2018. Long Term Effects of Cultivation on Physicochemical Properties of Soils at Metahara Sugar Estate. American- Eurasian Journal of Agricultural Research, 18: 246-257.
[3] Luciano, C., Jorge, M., Esperanza, H., Jose, D. 2017. Effect of Long-Term Sugarcane (Saccharum Spp.) Cultivation on Chemical and Physical Properties of Soils in Belize. Communication in soil science and plant analysis, 48: 741-755.
[4] Hamza, M. A. and Anderson, W. K. 2005. Soil compaction in cropping systems. A review of the nature, causes and possible solutions. Soil and Tillage Research, 82: 121-145.
[5] Albiach, k. 2003. Management practices to improve soil health and reduce the effects of detrimental soil biota associated with yield decline of sugarcane in Queensland, Australia. Soil Tillage Research, 72: 125-137.
[6] Pankhurst, C. E., Stirling, G. R., Magarey, R. C., Blair, B. C., Holt, J. A., Bell, M. J., Garside, A. L. 2005. Quantification of the effects of rotation breaks on soil biological properties and their impact on yield decline in sugarcane. Soil Biology and Biochemistry, 37: 1121-1130.
[7] Tesfaye, W., Kibebew, K., Bobe, B., Melesse, T. and Teklu, E. 2020a. Effects of Compaction at Different Moisture Contents on Selected Soil Properties and Sugarcane Growth and Sugar Yield at Metahara Sugar Estate. American Journal of Agricultural Research, 15: 78.
[8] Karlen, D. L., Kovar, J. L., Cambardella, C. A., and Colvin, T. S. 2013. Thirty-year tillage effects on crop yield and soil fertility indicators. Soil Till. Res., 130: 24-41.
[9] Tesfaye, W. 2021a. Extent of Soil Compaction under Mechanized Sugarcane Cultivation at Wonji-Shoa Sugar Estate. World Journal of Agricultural Sciences, 17: 338-350.
[10] Tesfaye, W. 2021c. Effectiveness of Sugar Industry Organic Wastes in Reducing Soil Compatibility in Soils of Three Ethiopian Sugar Estates. International Journal of Energy and Environmental Science, 6: 86-95.
[11] Tesfaye, W. 2021b. Long Term Sugarcane Cultivation Effect on Selected Physical and Hydraulic Properties of Soils at Three Ethiopian Sugarcane Estates. American Journal of Plant Biology, 6: 60-72.
[12] Taye Bekele and Hoefner W. (1993). Effects of different phosphate fertilizers on yield of barley and rapeseed on reddish brown soils of the Ethiopian highlands. Fertilizer Research 34: 243-250.
[13] Reichert, J. M., Eduardo, L., Suzuki, A. S., Reinert, D. J., Horn, R., Hakansson, I. 2009. Reference bulk density and critical degree-of-compactness for no-till crop production in subtropical highly weathered soils. Soil and Tillage, 102: 242–254.
[14] Ambachew, D., Abiy, F., Zeleke, T. 2012. Correlation of Foliar Nutrient Status with Yield of Sugarcane Varieties at Different Crop Stages and Nitrogen Levels at Wonji-Shoa and Finchaa Sugarcane Plantations of Ethiopia. Ethiop. J. Appl. Sci. Technol, 3: 9-22.
[15] ESC (Ethiopian Sugar Corporations). 2015. Ten Years (2003-2013) Climatic Data Obtained from the National Meteorological Agency of Wonji-Shoa, Metahara and Finchaa Stations. Ethiopian Sugar Corporation Research and Training Service Division, Addis Ababa, Ethiopia.
[16] Tadesse, N. 2004. Summary of Metahara Sugar Factory Weather Data for the Year 2004 and Average of the Last Ten Years (1993-2004). Ethiopian Sugar Industry Support Center, Research and Training Service Division, Wonji, Ethiopia.
[17] Michael, M. and Seleshi, B. 2007. Irrigation Practices in Ethiopia: Characteristics of Selected Irrigation Schemes. Integrated Water Management Institute, Colombo, Srilanka.
[18] Ambachew, D. and Abiy, F. 2009. Assessment of Some Soil Physicochemical Properties of Soils of Wonji-Shoa, Metahara and Finchaa Sugarcane Plantations. Annual research report. Ethiopian Sugar Corporation Research and Training Service Division, Wonji, Ethiopia. pp. 118-130.
[19] APECS (Agrima Project Engineering and Consultancy Services). 1987. A Report on the Agricultural Research Services of the Ethiopian Sugar Corporation (ESC). Matha Private, Bombay, India. pp. 1-414.
[20] Duiker, W., 2002. Diagnosing soil compaction using a penetrometer. Pennsylvania State University, Pennsylvania, USA.
[21] Girma, A. 2009. Effect of Filter Cake and Mineral Fertilizers on Yield of Plantcane in the Sugarcane Plantations of Ethiopia. Proc. Ethiop. Sugar. Ind. Bienn. Conf., 1: 126-136.
[22] Babbu, S. B., Jagdeep, S., Gurbir, S., Gurpreet, K. 2015. Effects of Long Term Application of Inorganic and Organic Fertilizers on Soil Organic Carbon and Physical Properties in Maize–Wheat Rotation. Agronomy, 5: 220-238.
[23] Okalebo, J. R., Gathua, K. W. and Womer, P. L. 2002. Laboratory Methods of Soil and Plant Analyses. A Working Manual, 2nd ed. TSBF–CIAT and SACRED Africa, Nairobi, Kenya.
[24] Soil Survey Staff, 1999. Soil Taxonomy. A basic system of soil classification for making and interpreting soil surveys. Second edition. Agriculture Handbook 436. Washington, DC, USDA. P 886.
[25] Jamison, V. C., Weaver, H. H. and Reed, I. F. 1950. A hammer-driven soil core sampler. Soil Science, 69: 487–496.
[26] Rao, M., Singa, P. and Raju, M. J. 2005. Laboratory Manual on Soil Physicochemical Properties. Aditha Art Printers, New Delhi, India.
[27] Rowell, D. L. 1994. Soil science: Method and Applications. Longman Scientific and Technical, Longman Group UK Limited Addison, Wesley, England. pp. 350.
[28] Peech, M. 1965. Hydrogen-ion activity. pp. 914-926. In: CA, Black, D. D. Evans, J. L. Ensminger and F. E. Clark (eds). Methods of Soil Analysis. Part II. ASA, WI, Madison, USA.
[29] Walkly, A. and Black, I. A. 1934. An Examination of digestion method for determining soil organic matter and a proposed modification of the chromic acid titration. Soil Science, 37: 29-38.
[30] Jackson, M. L. 1958. Soil Chemical Analysis. Prentice Hall, Inc., Englewood Cliffs. New Jersey.
[31] Olsen, S. R., Cole, C. V. Watanabe, L. and Dean, A. 1954. Estimation of Available P in Soils Extraction with NaHCO3. USDA Cir. 939, US Government Printing Office, Washington D. C., USA.
[32] Murphy, J and Riley, J P. 1962. A modified single solution method for the determination of phosphorus in natural waters. Analytica Chimica Acta, 27: 31-36.
[33] SAS (Statistical Analysis System). 2002. SAS Version 9.1.3. SAS Institute Inc., Cary, NC, USA.
[34] Yihenew Gebresilassie. (2002). Selected chemical and physical characteristics of soil Adet research center and its testing sites in north-western Ethiopia.
[35] Teklu Erkossa. (2005). Land preparation methods and soil quality of vertisol area in the central highlands of Ethiopia. Stuttgart: University at Hohenheim, 310: D-70593.
[36] Jones, C. A. 1983. Effect of soil texture on critical bulk densities for root growth. Soil Science Society of America Journal, 47: 1028–1211.
[37] Negessa, G. and Tesfaye, W. 2021. Influence of Organic and Chemical Source Fertilizers on Soil Physicochemical Properties and Nutrient Concentration of Nitisol in Welmera District, Central Ethiopia. World Journal of Agricultural Sciences, 17: 295-307.
[38] Ridge, R. 2013. Sugarcane Fertilizing for High Yield. IPI Bulletin No. 21. International Potash Institute, Coral Cove, Australia.
[39] Hillel, D. 1998. Environmental Soil Physics. Academic Press, London, England.
[40] Sarwar, A. M., Ibrahim, M., Tahir, M., Ahmad, K., Khan, I. Z. and Valeem, E. E. 2010. Appraisal of pressmud and inorganic fertilizers on soil properties, yield and sugarcane quality. Pakistan Journal of Botany, 42: 1361-1367.
[41] Hazelton, P. and Murphy, B. 2007. Interpreting Soil Test Results: What Do All the Numbers Mean? 2nd ed. CSIRO Publishing, Colling wood, Australia. pp. 169.
[42] Brady, N. C. and Weil, R. R. 2002. The Nature and Properties of Soils, 13th Ed. Prentice- Hall Inc. New Jersey, USA. pp. 960.
[43] Gangwar, K. S., Singh, K. K., Sharma, S. K., &Tomar, O. K., 2006. Alternative tillage and crop residue management in wheat after rice in sandy loam soils of Indo-Gangetic plains, Soil and Tillage Research, 88: 242-252.
[44] Mengistu, C. 2017. Influence of different land use types and soil depths on selected soil properties related to soil fertility in Warandhab Area, Horo Guduru Wallaga Zone, and Oromiya, Ethiopia.
[45] Meyer, J. H., Antwerpen, R. 2010. Advances in sugarcane soil fertility research in Southern Africa. South African Journal of Plant and Soil, 27: 19-31.
[46] Prasad, M. R. and Govardhan, V. 2011. Characterization and classification of soil and land resource environments of Deccan Plateau. Journal of Research ANGRAU, 39: 1-5.
[47] Barzegar, A. R., Mahmoodi, S. H., Hamedi, F. and Abdolvahabi, F. 2005. Long term sugarcane cultivation effects on physical properties of fine textured soils. Journal of Agricultural Science and Technology, 7: 59-68.
[48] Barzegar, A. R., Asoodar, M. A. and Ansari, M. 2000. Effectiveness of sugarcane residue incorporation at different water contents and the Proctor compaction loads in reducing soil compactibilty. Soil and Tillage Research, 57: 167-172.
[49] Ahmed, A., Dechassa, N., Gebeyehu, S., and Alemayehu, Y. 2018. 2018. Characterization of Soil of Jijiga Plain in the Somali Regional State of Ethiopia. East African Journal of Sciences, 12: 1-10.
[50] Smith, E. K., Misiewicz, P. A., Chaney, K., White, D. R., Godwin, R. J. 2013. An investigation into the effect of traffic and tillage on soil properties and crop yields. ASABE Paper No. 1597846. Kansas City, Missouri: ASABE.
[51] Tekalign, T. 1991. Soil, Plant, Water, Fertilizer, Animal Manure and Compost Analysis. Working Document No. 13. International Livestock Research Center for Africa, Addis Ababa, Ethiopia.
[52] Kannan, R. L., Dhivya, M., Abinaya, D., Krishna, R. L., Krishnakumar, S. 2013. Effect of integrated nutrient management on soil fertility and productivity in maize. Bull. Environ. Pharm. Life Sci., 2: 61-67.
[53] Pradeep, H. M. 2007. Studies on sugarcane based industrial wastes on maize-chickpea cropping sequence in Vertisols of North Karnataka. PhD thesis, Dharwad University, New Delhi, India.
[54] Arain, A. M., Ahmed, M. and Khan, A. M. 2000. Some physicochemical characteristics of soils in sugarcane cultivate areas of Nawabshah, Sindh, Pakistan. Pakistan Jornounal of Botony, 32: 93-100.
[55] BAI (Booker Agricultural International) in association with Generation Integrated Rural Development Consultant. 2009. Re-evaluation of the Plantation Soils at Metahara Sugar Factory. Final Report. BAI, London, England.
[56] Jones, J. B., 2003. Agronomic Handbook: Management of Crops, Soils, and Their Fertility. CRC Press LLC, Boca Raton, FL, USA. 482p.
[57] Tolera, E., Tesfaye, W. 2021. The Effect of Application of Vermicompost and NPS Fertilizer on Selected Soil Properties and Yield of Maize (Zea May L.) at Toke Kutaye, Ethiopia. International Journal of Applied Agricultural Sciences, 7: 247-257.
[58] Martín-L. D., Tenorio, L., Albarrán, M. M., Zambrana, E., and Walter I. 2013. Influence of tillage practices on soil biologically active organic matter content over a growing season under semiarid Mediterranean climate. Spanish J. Agric. Res., 11: 232-243.
[59] Tesfaye, W., Kibebew, K., Bobe, B., Melesse, T. and Teklu, E. 2020b. Effects of long term sugarcane production on soils physicochemical properties at Finchaa sugar Estate. Journal of Soil Science and Environmental Management, 11: 30-40.
[60] Alvarez, C. R.; Taboada, M. A., Gutierrez, F. H.; Fernandez, P. L. and Prystupa, P. 2009. Topsoil properties as affected by tillage systems in the Rolling Pampa region of Argentina. Soil Science Society of American Journal, 73: 242-1250.
[61] Botta, GF, Tolon, B. A., Bellora, T. F. 2009. Effect of the numberof tractor passes on soil rut depth and compaction in two tillageregimes. Soil Till Res.; 103: 381-6.
[62] Berhanu, D. 1980. The physical criterion and their rating proposed for land evaluation in the highland regions of Ethiopia, Land Uses Planning and Regulatory Department, Ministry of Agriculture, Addis Ababa, Ethiopia.
[63] Bikila, T. 2018. Effects of Lime and Compost on acidic Soil Amelioration and Growth of Coffee (Coffea Arabica L.) Seedlings at Haru, West Wollega. M.Sc. Thesis Submitted to School of Graduate Studies of Jimma University College of Agriculture and Veterinary Medicine, Department of Natural Resource Management.
[64] Muscoloa, A., Bovalob, F., Gionfriddob, F., Nardi, S. 1999. Earthworm humic matter produces auxin-like effects on Daucuscarota cell growth and nitrate metabolism. Soil Biology and Biochemistry, 31: 1303–1311.
[65] Tisdale, S. L., Nelson, W. L, Beaton, J. D. and Havlin, J. L. 1995. Soil Fertility and Fertilizer, 5th Ed. Prentice-Hall of India, New Delhi, India. 684p.
[66] Tesfaye, W., Kibebew, K., Bobe, B., Melesse, T. and Teklu, E. 2019. Effects of Subsoiling and Organic Amendments on Selected Soil Physicochemical Properties and Sugar Yield in Metahara Sugar Estate. American- Eurasian Journal of Agricultural Research, 19: 312-325.
[67] Newey, A. 2006. Litter carbon turnover with depth. PhD Thesis, Australian National University, Canberra, Australia.
[68] Naranjo, F. J., Salgado, S., Lagunes, L. C., Carrillo, E. & Plama, D. J. 2006. Change in the properties of a Mexican Fluvisol fllowing 30 years of sugarcane cultivation. Soil & Tillage Research, 88: 160-167.
[69] Sahlemedhin, S. and Taye, B. 2007. Procedure for soil and plant analysis Technical Bulletin No. 74. National Soil Research Center, Ethiopian Agricultural Organization, Addis Ababa, Ethiopia.
[70] Muhammad, S., Gafoor, A., Hussain, T. and Rauf, A. 1990. Management of salt affected soils for sustainable agriculture Proc. 3rd National congress of soil science. March 20-22 p 28-39.
[71] Landon, J. R. 2014. Booker Tropical Soil Manual: A Hand Book for Soil Survey and Agricultural Land Evaluation in the Tropics and Subtropics. Booker Tate limited, London, England.
[72] Tekalign, M. and Haque, I. 1991. Phosphorus status of some Ethiopian soils. III. Evaluation of some soil test methods for available phosphorus. Tropical Agriculture, 68: 51-56.
[73] Birru, Y. 1999. Phosphorus status and sorption characteristics of the soils of the Northwestern highlands of Ethiopia. MSc Thesis, Alemaya University, Haramaya, Ethiopia.
[74] Murphy, H. F. 1968. A report on fertility status and other data on some soils of Ethiopia. Collage of Agriculture HSIU. Experimental Station Bulletin No. 44, Collage of Agriculture: 551p.
[75] Yadava, R. L. 1991. Sugarcane production technology constraints and potentialities. Oxford and IBH publishing Co. Pvt Ltd. New Dehli. pp. 291.
[76] Angelova, V. R., V. I. Akova, N. S., Artinova and K, Ivanov, 2013. The effect of organic amendments on soil chemical characteristics, Bulgarian Journal of Agricultural Science 19: 958–71.
[77] Wakene, N. 2001. Assessment of important physicochemical properties of Dystric Udalf (Dystric Nitosols) under different management systems in Bako area, Western Ethiopia. MSc Thesis, Alemaya University, Haramaya, Ethiopia.
[78] FAO (Food and Cultivated Organization). 2006. Plant Nutrition for Food Security: A guide for integrated nutrient management. FAO Fertilizer and Plant Nutrition Bulletin Food and Agriculture Organization, Rome, Italy.
[79] Dang, M. 2007. Quantitative and qualitative soil quality assessments of tea enterprises in Northern Vietnam. Vietnam. African Journal of Agricultural Research 2: 455-462.
[80] Ahmed, H. 2002. Assessment of spatial variability of some physicochemical properties of soils under different elevations and land use systems in the western slopes of Mount Chilalo, Arsi. MSc Thesis, Alemaya University, Haramya, Ethiopia.
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    Tesfaye Wakgari. (2021). Status of Selected Physicochemical Properties of Soils Under Long Term Sugarcane Cultivation Fields at Wonji-Shoa Sugar Estate. American Journal of Agriculture and Forestry, 9(6), 397-408. https://doi.org/10.11648/j.ajaf.20210906.19

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    Tesfaye Wakgari. Status of Selected Physicochemical Properties of Soils Under Long Term Sugarcane Cultivation Fields at Wonji-Shoa Sugar Estate. Am. J. Agric. For. 2021, 9(6), 397-408. doi: 10.11648/j.ajaf.20210906.19

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    Tesfaye Wakgari. Status of Selected Physicochemical Properties of Soils Under Long Term Sugarcane Cultivation Fields at Wonji-Shoa Sugar Estate. Am J Agric For. 2021;9(6):397-408. doi: 10.11648/j.ajaf.20210906.19

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  • @article{10.11648/j.ajaf.20210906.19,
  author = {Tesfaye Wakgari},
  title = {Status of Selected Physicochemical Properties of Soils Under Long Term Sugarcane Cultivation Fields at Wonji-Shoa Sugar Estate},
  journal = {American Journal of Agriculture and Forestry},
  volume = {9},
  number = {6},
  pages = {397-408},
  doi = {10.11648/j.ajaf.20210906.19},
  url = {https://doi.org/10.11648/j.ajaf.20210906.19},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajaf.20210906.19},
  abstract = {A declining trend in per hectare yield of sugarcane in Wonji-Shoa Sugar Estate is being observed due to altering of soil physicochemical properties resulted from long term sugarcane cultivation. Cognizant of this fact, a study was conducted in 2017at Wonji-Shoa Sugar Estate with the objective of determining the effects of more than 62 years of sugarcane cultivation on the physicochemical properties of soil. In order to achieve this objective disturbed and undisturbed soil samples were collected from 0-30 and 30-60 cm layers of selected cultivated and uncultivated light and heavy soils for laboratory analysis. Results of the study indicated that long term cultivation of sugarcane at the same depth and low soil organic matter content of cultivated fields induced soil compaction and consequently highest bulk density was recorded in subsoil layer of cultivated than uncultivated land. The bulk density and total porosity values were out of ranges recommended for optimum sugarcane cultivation and suggest the existence of some degree of compaction. The finding further showed that the pH of study area soils is out of the normal pH range for sugarcane plant growth. The soil organic carbon, total nitrogen content and available phosphorus concentration of soils under both land uses of all soils was found within low range. Therefore, based on the result of the study it can be concluded that under condition of strong base soil pH of study area the availability of essential nutrients are critically affected. This indicates that the strong pH values at Wonji-Shoa Estate require more attention. Moreover, the low levels of organic carbon, total nitrogen, and available P contents under both cultivated and uncultivated soils indicated that soil fertility is among the constraints for sustainable sugarcane production in the estate. Based on the findings and conclusions of this study one can recommend that to maintain sustainability of sugarcane production in the estate soil management practices that can protect as well as ameliorate soil compaction, increase soil organic carbon, total nitrogen, soil available P and that can decrease soil pH are important. Nevertheless, in order to give conclusive recommendation further research studies are needed for more soil management units in the estate.},
 year = {2021}
}

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  • TY  - JOUR
T1  - Status of Selected Physicochemical Properties of Soils Under Long Term Sugarcane Cultivation Fields at Wonji-Shoa Sugar Estate
AU  - Tesfaye Wakgari
Y1  - 2021/11/25
PY  - 2021
N1  - https://doi.org/10.11648/j.ajaf.20210906.19
DO  - 10.11648/j.ajaf.20210906.19
T2  - American Journal of Agriculture and Forestry
JF  - American Journal of Agriculture and Forestry
JO  - American Journal of Agriculture and Forestry
SP  - 397
EP  - 408
PB  - Science Publishing Group
SN  - 2330-8591
UR  - https://doi.org/10.11648/j.ajaf.20210906.19
AB  - A declining trend in per hectare yield of sugarcane in Wonji-Shoa Sugar Estate is being observed due to altering of soil physicochemical properties resulted from long term sugarcane cultivation. Cognizant of this fact, a study was conducted in 2017at Wonji-Shoa Sugar Estate with the objective of determining the effects of more than 62 years of sugarcane cultivation on the physicochemical properties of soil. In order to achieve this objective disturbed and undisturbed soil samples were collected from 0-30 and 30-60 cm layers of selected cultivated and uncultivated light and heavy soils for laboratory analysis. Results of the study indicated that long term cultivation of sugarcane at the same depth and low soil organic matter content of cultivated fields induced soil compaction and consequently highest bulk density was recorded in subsoil layer of cultivated than uncultivated land. The bulk density and total porosity values were out of ranges recommended for optimum sugarcane cultivation and suggest the existence of some degree of compaction. The finding further showed that the pH of study area soils is out of the normal pH range for sugarcane plant growth. The soil organic carbon, total nitrogen content and available phosphorus concentration of soils under both land uses of all soils was found within low range. Therefore, based on the result of the study it can be concluded that under condition of strong base soil pH of study area the availability of essential nutrients are critically affected. This indicates that the strong pH values at Wonji-Shoa Estate require more attention. Moreover, the low levels of organic carbon, total nitrogen, and available P contents under both cultivated and uncultivated soils indicated that soil fertility is among the constraints for sustainable sugarcane production in the estate. Based on the findings and conclusions of this study one can recommend that to maintain sustainability of sugarcane production in the estate soil management practices that can protect as well as ameliorate soil compaction, increase soil organic carbon, total nitrogen, soil available P and that can decrease soil pH are important. Nevertheless, in order to give conclusive recommendation further research studies are needed for more soil management units in the estate.
VL  - 9
IS  - 6
ER  -

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  • Tesfaye Wakgari

    College of Natural Resource Management and Veterinary Science, Ambo University, Ambo, Ethiopia

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