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Effects of Different Soil Conditioners on Water Use Efficiency and Tomato Plant Growth in Loam and Clay Loam Soils

Year 2021, Volume: 9 Issue: 1, 153 - 161, 28.06.2021
https://doi.org/10.33202/comuagri.911660

Abstract

A pot experiment was conducted applying 8% olive pomace compost, 4% perlite and 0.12% hydrophilic polymers on loam and clay loam soils with three replications. Tomato (Lycopersicon lycopersicum L.) seedlings were transferred to each pot and plants were grown under controlled atmosphere conditions. Effects of different soil conditioners on plant water use efficiency and tomato plant growth was determined. As a result, olive pomace compost applications to loam soil saved irrigation water 45.12%, 42.99% and 38.88% compared to control, perlite and hydrophilic polymers treatments respectively. On the other hand, hydrophilic polymers treatments saved irrigation water 17.82%, 46.76% and 27.29% compared to control, perlite and olive pomace compost treatments respectively for clay loam soil. Soil pH decreased and electrical conductivity (EC) increased for both soils after the experiment. The highest soil EC value was dedected with the application of olive pomace compost. Perlite application increased plant fresh weight and length while olive pomace compost increased branch numbers of tomato for clay loam soil. Root length and surface areas were maximum under olive pomace compost applications for both soils.

Supporting Institution

ÇOMÜ-BAP

Project Number

2012/18

References

  • Abedi-Koupai, J., Asadkazemi, J., 2006. Effects of a hydrophilic polymer on the field performance of cupressus arizonica under reduced irrigation regimes. Iranian Polymer Journal. 15(9):715-725.
  • Akhter, J., Mahmood, K., Malik, K. A., Mardan, A., Ahmad, M., Iqbal, M. M. (2004). Effects of hydrogel amendment on water storage of sandy loam and loam soils and seedling growth of barley, wheat and chickpea. Plant Soil and Environment. 50(10): 463-469.
  • Bai, W., Zhang, H., Liu, B., Wu, Y., Song, J., 2010. Effects of super-absorbent polymers on the physical and chemical properties of soil following different wetting and drying cycles. Soil Use and Management. 26(3): 253-260.
  • Banedjschafie, S., Durner, W., 2015.Water retention properties of a sandy soil with superabsorbent polymers as affected by aging and water quality. Journal of Plant Nutrition and Soil Science. 178 (5): 798-806.
  • Black, C. A., 1965. Methods of Soil Analysis Part-II. American Soc. of Agronomy Inc., Publisher Madison Wisconsin, USA: 1372-1376.
  • Bouranis, D.L., Vlyssides, A.G., Drossopoulos, J.B., Karvouni, G. 1995. Some characteristics of a new organic soil conditioner from the co‐composting of olive oil processing wastewater and solid residue. Communications in Soil Science and Plant Analysis. 26(15-16): 2461-2472.
  • Bowman, D.C., Evans, R.Y., 1991. Calcium inhibition of polyacrylamide gel hydration is partially reversible by potassium. HortScience. 26 (8): 1063-1065. Brady, N. C., Weil, R. R., 2008.The nature and properties of soils. 13: 662-710. Upper Saddle River, NJ: Prentice Hall.
  • Cardenas-Lailhacar, B.C., Dukes, M.D., 2010.Precision of soil moisture sensor irrigation controllers under field conditions. Agricultural Water Management. 97(5) 666-672.
  • Caron, J., Rivière, L.M., Guillemain, G., 2005. Gas diffusion and air-filled porosity: Effect of some oversize fragments in growing media. Canadian Journal of Soil Science. 85(1): 57-65.
  • Cucci, G., Lacolla, G., Caranfa, L., 2008. Improvement of soil properties by application of olive oil waste. Agronomy for sustainable development. 28(4): 521-526.
  • Demirel, K., Kavdır, Y., 2013. Effect of soil water retention barriers on turfgrass growth and soil water content. Journal of Irrigation Science. 31(4): 689-700.
  • El-Asswad, R. M., Said, A. O., Mornag, M. T., 1993. Effect of olive oil cake on water holding capacity of sandy soils in Libya Journal of arid environments. 24(4), 409-413.
  • Evans, M.R., Gachukia, M., 2004. Fresh parboiled rice hulls serve as an alternative to perlite in greenhouse crop substrates. HortScience. 39(2): 232-235.
  • Evans, M.R., Gachukia, M.M., 2007. Physical properties of sphagnum peat-based root substrates amended with perlite or parboiled fresh rice hulls. HortTechnology. 17(3) 312-315.
  • Fazackerley S. and Lawrence R., 2010. Reducing turfgrass water consumption using sensor nodes and an adaptive ırrigation controller. Retrieved December 5, 2010, from: https//people.ok.ubc.ca/rlawrenc/research/Papers/IEEESAS2010.pdf. Accessed 10 Mar. 2012.
  • Gee, G.W., Bauder, J.W., 1986. Particle-size analysis. In: Klute, A. (Ed.), Methods of Soil Analysis, Part 1. Physical and Mineralogical Methods, 2nd ed. Agron. 9, American Society of Agronomy, Madison, WI: 383–413
  • Gonzalez, M.D., Moreno, E., Quevedo-Sarmiento, J., Ramos-Cormenzana, A., 1990. Studies on antibacterial activity of waste waters from olive oil mills (alpechin): inhibitory activity of phenolic and fatty acids.Chemosphere. 20(3-4): 423-432.
  • Hachicha, S., Chtourou, M., Medhioub, K., Ammar, E., 2006.Compost of poultry manure and olive mill wastes as an alternative fertilizer. Agronomy for Sustainable Development 26(2): 135-142.
  • Han, Y. G., Yang, P. L., Luo, Y. P., Ren, S. M., Zhang, L. X., Xu, L., 2010. Porosity change model for watered super absorbent polymer-treated soil. Environmental Earth Sciences. 61(6): 1197-1205.
  • Ilay, R., Kavdir, Y., Sümer, A., 2013. The effect of olive oil solid waste application on soil properties and growth of sunflower (Helianthus annuus L.) and bean (Phaseolus vulgaris L.). International Biodeterioration & Biodegradation. 85: 254-259.
  • Johnson, M.S., 1984. The effects of gel‐forming polyacrylamides on moisture storage in sandy soils. Journal of the Science of Food and Agriculture. 35(11): 1196-1200. Kavdir, Y., Killi, D., 2008. Influence of olive oil solid waste applications on soil pH, electrical conductivity, soil nitrogen transformations, carbon content and aggregate stability. Bioresource Technology. 99(7): 2326-2332.
  • Keever, G.J., Cobb G.S., Stephenson J.C. and Foster W.J., 1989. Effect of hydrophylic polymer amendment on growth of container grown landscape plants. J.Environ. Hort. 7 (2): 52-56.
  • Killi, D., Anlauf, R., Kavdir, Y., Haworth, M., 2014. Assessing the impact of agro-industrial olive wastes in soil water retention: Implications for remediation of degraded soils and water availability for plant growth. International Biodeterioration & Biodegradation. 94: 48-56.
  • Leib, B.G., Jabro, J.D., Matthews, G.R., 2003. Field evaluation and performance comparison of soil moisture sensors. Soil Science 168 (6): 396-408.
  • López-Elías, J., Huez, L., Rueda, P., Jiménez, L., Cruz, B., & Garrido, L. (2013). Use of a hydrophilic polymer in Anaheim pepper (Capsicum annuum L.) under greenhouse conditions. Idesia, 31(2), 77-81.
  • Mazen, A.M., Radwan, D.E.M., Ahmed, A.F., 2013. Conditioning effect of different absorbant polymers on physical and chemical properties of sandy soil. Journal of Functional and Environmental Botany.3(2): 82-93.
  • Montemurro, F., Convertini, G., Ferri, D., 2004. Mill wastewater and olive pomace compost as amendments for rye-grass. Agronomie. 24(8): 481-486.
  • Nektarios, P.A., Ntoulas, N., McElroy, S., Volterrani, M., Arbis, G., 2011.Effect of olive mill compost on native soil characteristics and tall fescue turfgrass development. Agronomy journal. 103(5): 1524-1531.
  • Ntoulas, N., Nektarios, P.A., Gogoula, G., 2011. Evaluation of olive mill waste compost as a soil amendment for Cynodon dactylon turf establishment, growth and anchorage. HortScience. 46(6): 937-945.
  • Ozenc, B. D., Ozkan, I., 2003. Effect of peat and perlite mixed with soil on growth of pepper plant (Capsicum annuum var. grossum cv. 11B-14) under water stress. Journal of Agricultural Sciences. 9 (3): 305-312.
  • Papafotiou M., Kargas G., Lytra I., 2005. Olive-mill Waste Compost as a Growth Medium Component for Foliage Potted Plants. HortScience. 40(6): 1746–1750. Richards, L.A.,1954. Diagnosis and improvement of saline and alkali soils. United States salinity laboratory staff. United States Department of Agriculture Handbook. 60-160.
  • Romano, N., Santini, A., 2002. Water retention and storage: Field. In “Methods of Soil Analysis, Part 4, Physical Methods”. Dane, J.H., Topp, G.C., (Eds.), SSSA Book Series N.5, Madison, WI, USA: 721-738.
  • SAS, S.,1999. OnlineDoc®, Version 8.SAS Institute, Cary, North Carolina. USA.
  • Starr, J.L., Paltineanu, I.C., 1998. Real-time soil water dynamics over large areas using multisensor capacitance probes and monitoring system. Soil and Tillage Research. 47(1-2) 43-49.
  • Starr, J.L., Paltineanu, I.C., 2002. Methods for measurement of soil water content: Capacitance Devices. In: Dane, J.H., Topp, G.C., (Eds.), Methods of Soil Analysis: Part 4, Physical Methods. Soil Science Society of America, Inc., Madison, WI. 463- 474.
  • Topp, G. C., 2003. State of the art of measuring soil water content. Hydrological Processes. 17 (14): 2993-2996.
  • Wallace, A., Wallace, G. A., 1986. Effects of very low rates of synthetic soil conditioners on soils. Soil Science. 141(5): 324-327.
  • Yang, L., Yang, Y., Chen, Z., Guo, C., Li, S., 2014. Influence of super absorbent polymer on soil water retention, seed germination and plant survivals for rocky slopes eco-engineering. Ecological Engineering. 62: 27-32.
  • Yurkov, A. L., Aksel'rod, L. M., 2005. Properties of heat-insulating materials (a review). Refractories and Industrial Ceramics. 46(3): 170-174.

Effects of Different Soil Conditioners on Water Use Efficiency and Tomato Plant Growth in Loam and Clay Loam Soils

Year 2021, Volume: 9 Issue: 1, 153 - 161, 28.06.2021
https://doi.org/10.33202/comuagri.911660

Abstract

A pot experiment was conducted applying 8% olive pomace compost, 4% perlite and 0.12% hydrophilic polymers on loam and clay loam soils with three replications. Tomato (Lycopersicon lycopersicum L.) seedlings were transferred to each pot and plants were grown under controlled atmosphere conditions. Effects of different soil conditioners on plant water use efficiency and tomato plant growth was determined. As a result, olive pomace compost applications to loam soil saved irrigation water 45.12%, 42.99% and 38.88% compared to control, perlite and hydrophilic polymers treatments respectively. On the other hand, hydrophilic polymers treatments saved irrigation water 17.82%, 46.76% and 27.29% compared to control, perlite and olive pomace compost treatments respectively for clay loam soil. Soil pH decreased and electrical conductivity (EC) increased for both soils after the experiment. The highest soil EC value was dedected with the application of olive pomace compost. Perlite application increased plant fresh weight and length while olive pomace compost increased branch numbers of tomato for clay loam soil. Root length and surface areas were maximum under olive pomace compost applications for both soils.

Project Number

2012/18

References

  • Abedi-Koupai, J., Asadkazemi, J., 2006. Effects of a hydrophilic polymer on the field performance of cupressus arizonica under reduced irrigation regimes. Iranian Polymer Journal. 15(9):715-725.
  • Akhter, J., Mahmood, K., Malik, K. A., Mardan, A., Ahmad, M., Iqbal, M. M. (2004). Effects of hydrogel amendment on water storage of sandy loam and loam soils and seedling growth of barley, wheat and chickpea. Plant Soil and Environment. 50(10): 463-469.
  • Bai, W., Zhang, H., Liu, B., Wu, Y., Song, J., 2010. Effects of super-absorbent polymers on the physical and chemical properties of soil following different wetting and drying cycles. Soil Use and Management. 26(3): 253-260.
  • Banedjschafie, S., Durner, W., 2015.Water retention properties of a sandy soil with superabsorbent polymers as affected by aging and water quality. Journal of Plant Nutrition and Soil Science. 178 (5): 798-806.
  • Black, C. A., 1965. Methods of Soil Analysis Part-II. American Soc. of Agronomy Inc., Publisher Madison Wisconsin, USA: 1372-1376.
  • Bouranis, D.L., Vlyssides, A.G., Drossopoulos, J.B., Karvouni, G. 1995. Some characteristics of a new organic soil conditioner from the co‐composting of olive oil processing wastewater and solid residue. Communications in Soil Science and Plant Analysis. 26(15-16): 2461-2472.
  • Bowman, D.C., Evans, R.Y., 1991. Calcium inhibition of polyacrylamide gel hydration is partially reversible by potassium. HortScience. 26 (8): 1063-1065. Brady, N. C., Weil, R. R., 2008.The nature and properties of soils. 13: 662-710. Upper Saddle River, NJ: Prentice Hall.
  • Cardenas-Lailhacar, B.C., Dukes, M.D., 2010.Precision of soil moisture sensor irrigation controllers under field conditions. Agricultural Water Management. 97(5) 666-672.
  • Caron, J., Rivière, L.M., Guillemain, G., 2005. Gas diffusion and air-filled porosity: Effect of some oversize fragments in growing media. Canadian Journal of Soil Science. 85(1): 57-65.
  • Cucci, G., Lacolla, G., Caranfa, L., 2008. Improvement of soil properties by application of olive oil waste. Agronomy for sustainable development. 28(4): 521-526.
  • Demirel, K., Kavdır, Y., 2013. Effect of soil water retention barriers on turfgrass growth and soil water content. Journal of Irrigation Science. 31(4): 689-700.
  • El-Asswad, R. M., Said, A. O., Mornag, M. T., 1993. Effect of olive oil cake on water holding capacity of sandy soils in Libya Journal of arid environments. 24(4), 409-413.
  • Evans, M.R., Gachukia, M., 2004. Fresh parboiled rice hulls serve as an alternative to perlite in greenhouse crop substrates. HortScience. 39(2): 232-235.
  • Evans, M.R., Gachukia, M.M., 2007. Physical properties of sphagnum peat-based root substrates amended with perlite or parboiled fresh rice hulls. HortTechnology. 17(3) 312-315.
  • Fazackerley S. and Lawrence R., 2010. Reducing turfgrass water consumption using sensor nodes and an adaptive ırrigation controller. Retrieved December 5, 2010, from: https//people.ok.ubc.ca/rlawrenc/research/Papers/IEEESAS2010.pdf. Accessed 10 Mar. 2012.
  • Gee, G.W., Bauder, J.W., 1986. Particle-size analysis. In: Klute, A. (Ed.), Methods of Soil Analysis, Part 1. Physical and Mineralogical Methods, 2nd ed. Agron. 9, American Society of Agronomy, Madison, WI: 383–413
  • Gonzalez, M.D., Moreno, E., Quevedo-Sarmiento, J., Ramos-Cormenzana, A., 1990. Studies on antibacterial activity of waste waters from olive oil mills (alpechin): inhibitory activity of phenolic and fatty acids.Chemosphere. 20(3-4): 423-432.
  • Hachicha, S., Chtourou, M., Medhioub, K., Ammar, E., 2006.Compost of poultry manure and olive mill wastes as an alternative fertilizer. Agronomy for Sustainable Development 26(2): 135-142.
  • Han, Y. G., Yang, P. L., Luo, Y. P., Ren, S. M., Zhang, L. X., Xu, L., 2010. Porosity change model for watered super absorbent polymer-treated soil. Environmental Earth Sciences. 61(6): 1197-1205.
  • Ilay, R., Kavdir, Y., Sümer, A., 2013. The effect of olive oil solid waste application on soil properties and growth of sunflower (Helianthus annuus L.) and bean (Phaseolus vulgaris L.). International Biodeterioration & Biodegradation. 85: 254-259.
  • Johnson, M.S., 1984. The effects of gel‐forming polyacrylamides on moisture storage in sandy soils. Journal of the Science of Food and Agriculture. 35(11): 1196-1200. Kavdir, Y., Killi, D., 2008. Influence of olive oil solid waste applications on soil pH, electrical conductivity, soil nitrogen transformations, carbon content and aggregate stability. Bioresource Technology. 99(7): 2326-2332.
  • Keever, G.J., Cobb G.S., Stephenson J.C. and Foster W.J., 1989. Effect of hydrophylic polymer amendment on growth of container grown landscape plants. J.Environ. Hort. 7 (2): 52-56.
  • Killi, D., Anlauf, R., Kavdir, Y., Haworth, M., 2014. Assessing the impact of agro-industrial olive wastes in soil water retention: Implications for remediation of degraded soils and water availability for plant growth. International Biodeterioration & Biodegradation. 94: 48-56.
  • Leib, B.G., Jabro, J.D., Matthews, G.R., 2003. Field evaluation and performance comparison of soil moisture sensors. Soil Science 168 (6): 396-408.
  • López-Elías, J., Huez, L., Rueda, P., Jiménez, L., Cruz, B., & Garrido, L. (2013). Use of a hydrophilic polymer in Anaheim pepper (Capsicum annuum L.) under greenhouse conditions. Idesia, 31(2), 77-81.
  • Mazen, A.M., Radwan, D.E.M., Ahmed, A.F., 2013. Conditioning effect of different absorbant polymers on physical and chemical properties of sandy soil. Journal of Functional and Environmental Botany.3(2): 82-93.
  • Montemurro, F., Convertini, G., Ferri, D., 2004. Mill wastewater and olive pomace compost as amendments for rye-grass. Agronomie. 24(8): 481-486.
  • Nektarios, P.A., Ntoulas, N., McElroy, S., Volterrani, M., Arbis, G., 2011.Effect of olive mill compost on native soil characteristics and tall fescue turfgrass development. Agronomy journal. 103(5): 1524-1531.
  • Ntoulas, N., Nektarios, P.A., Gogoula, G., 2011. Evaluation of olive mill waste compost as a soil amendment for Cynodon dactylon turf establishment, growth and anchorage. HortScience. 46(6): 937-945.
  • Ozenc, B. D., Ozkan, I., 2003. Effect of peat and perlite mixed with soil on growth of pepper plant (Capsicum annuum var. grossum cv. 11B-14) under water stress. Journal of Agricultural Sciences. 9 (3): 305-312.
  • Papafotiou M., Kargas G., Lytra I., 2005. Olive-mill Waste Compost as a Growth Medium Component for Foliage Potted Plants. HortScience. 40(6): 1746–1750. Richards, L.A.,1954. Diagnosis and improvement of saline and alkali soils. United States salinity laboratory staff. United States Department of Agriculture Handbook. 60-160.
  • Romano, N., Santini, A., 2002. Water retention and storage: Field. In “Methods of Soil Analysis, Part 4, Physical Methods”. Dane, J.H., Topp, G.C., (Eds.), SSSA Book Series N.5, Madison, WI, USA: 721-738.
  • SAS, S.,1999. OnlineDoc®, Version 8.SAS Institute, Cary, North Carolina. USA.
  • Starr, J.L., Paltineanu, I.C., 1998. Real-time soil water dynamics over large areas using multisensor capacitance probes and monitoring system. Soil and Tillage Research. 47(1-2) 43-49.
  • Starr, J.L., Paltineanu, I.C., 2002. Methods for measurement of soil water content: Capacitance Devices. In: Dane, J.H., Topp, G.C., (Eds.), Methods of Soil Analysis: Part 4, Physical Methods. Soil Science Society of America, Inc., Madison, WI. 463- 474.
  • Topp, G. C., 2003. State of the art of measuring soil water content. Hydrological Processes. 17 (14): 2993-2996.
  • Wallace, A., Wallace, G. A., 1986. Effects of very low rates of synthetic soil conditioners on soils. Soil Science. 141(5): 324-327.
  • Yang, L., Yang, Y., Chen, Z., Guo, C., Li, S., 2014. Influence of super absorbent polymer on soil water retention, seed germination and plant survivals for rocky slopes eco-engineering. Ecological Engineering. 62: 27-32.
  • Yurkov, A. L., Aksel'rod, L. M., 2005. Properties of heat-insulating materials (a review). Refractories and Industrial Ceramics. 46(3): 170-174.
There are 39 citations in total.

Details

Primary Language English
Subjects Agricultural Engineering
Journal Section Articles
Authors

Nurten İşler 0000-0001-7879-6959

Yasemin Kavdır 0000-0002-2527-7685

Project Number 2012/18
Publication Date June 28, 2021
Published in Issue Year 2021 Volume: 9 Issue: 1

Cite

APA İşler, N., & Kavdır, Y. (2021). Effects of Different Soil Conditioners on Water Use Efficiency and Tomato Plant Growth in Loam and Clay Loam Soils. COMU Journal of Agriculture Faculty, 9(1), 153-161. https://doi.org/10.33202/comuagri.911660