Awe Gabriel OLADELE, Ayuba Margret BUSOLA, Umam JAPHET, Abegunrin Toyin PETER

Short-Term Impact of Drip Irrigation Frequency on Soil Hydro-Physical Properties of an Alfisol and Performance of Two Maize Varieties

Irrigation scheduling is important for efficient use of applied water and for maximizing crop yields. Therefore, the aim of this study was to evaluate the short-term effect of drip irrigation frequency on soil hydro-physical properties of an Alfisol and performance of two maize varieties, at the Teaching and Research Farm, Faculty of Agricultural Sciences, Ekiti State University, Ado Ekiti, Southwest Nigeria. The experiment was laid out using a split-plot experiment in randomized complete block design (RCBD) and three replications. Irrigation frequency constituted the main plot namely: irrigation four times a week (I4), irrigation thrice a week (I3), and irrigation twice a week (I2) of re-filling soil to field capacity while the subplot was maize variety namely: V1: SAMMAZ-27 and V2: OBA-super-6. Plant growth parameters and soil physical properties of soil water content (SWC), bulk density (BD) and saturated hydraulic conductivity (Ksat) were monitored during the growing cycle. Water use efficiency (WUE) and yield components were determined at maturity. There were significant interactions between irrigation regime and maize variety on SWC and Ksat. The maximum bulk density (BDmax) and optimum soil water content SWCopt were 1.41 g/cm3 and 0.12 g/g, respectively. Plant height (PH) did not differ between the two maize varieties throughout the growth cycle. Drip irrigation frequency did not significantly affect plant height until growth stage V12 (12 fully opened leaves), with I4 irrigation treatment having the tallest plant. Both drip irrigation and maize variety had no significant influence on both LAI and CC, neither was there any significant interaction effect. Increasing irrigation water increased maize yield and yield components. The treatment combination of I4V1 had the highest performance indices in terms of yield components. WUE decreased with increasing frequency of irrigation water application while the WUE of SAMMAZ-27 > OBA-super-6. Therefore, irrigating four times a week and SAMAZ27 maize variety could be a suitable irrigation-variety combination for providing sustainable irrigation agriculture for maize in this region.

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Abbas M. 2010. Effects of different levels of irrigation on maize yield, water use efficiency and soil properties under different sowing methods. MSc Dissertation in Soil Science, Institute of Soil and Environmental Sciences, faculty of Agriculture, University of Agriculture, Faisalabad, Pakistan, 106 pp.

Abd El-Hafez SA, El-Sabbagh AA, El-Bably AZ, Abou-Ahmed EI. 2001. Responses of maize crop to drip irrigation in clay soils. Alex. J. Agric. Res., 46(2): 153-159.

Abd El-Wahed MH, Ali EA. 2013. Effects of irrigation system, amounts of irrigation water and mulching on corn yield, water use efficiency and net profit. Agric. Water Manage, 120(31): 64-71.

Assouline S. 2002. The effects of micro drip and conventional drip irrigation on water distribution and uptake. Soil Science Sc. Am. J., 66(5): 1630-1636.

Awe GO, Fasina AS, Shittu OS, Jejelowo TA, Oparemi AD. 2016. Effects of drip irrigation frequency and N-fertilization on soil physical properties, yield and water use efficiency of cucumber (Cucumis sativus L.) in Ado Ekiti, southwestern Nigeria. Journal of Biology, Agriculture and Healthcare, 6(4): 32-46.

Awe GO, Fasina AS, Shittu OS, Omotoso SO. 2017. Irrigation and nutrient management for crop production: Maize (Zea mais) performance, resource use efficiency, and temporal variability of some soil physical properties. Journal, of Biology, Agriculture and Healthcare, 7(14): 33-47.

Blake GR, Hartge KH (1986). Bulk density. In Methods of Soil Analysis: Part 1- physical and mineralogical methods pp 377- 382.

Bouyoucous GJ. 1962. Hydrometer method improved for making particle size analyses of soils. Agronomy Journal 54(5):464- 465.

Cakir R. 2004. Effect of water stress at different development stages on vegetative and reproductive growth of maize. Field Crops Research, 89: 1-16.

Chen Z, Han Y, Ning K, Luo C, Sheng W, Wang S, Fan S, Wang Y, Wang Q. 2019. Assessing the performance of different irrigation systems on lettuce (Lactuca sativa L.) in the greenhouse. PLoS ONE, 14(2): e0209329. https://doi.org/ 10.1371/journal. pone.0209329

Clark L. 2004. Changesin properties of vineyard red brown earths under long-term drip irrigation, combined with varying water qualities and gypsum application rates. PhD Thesis, The University of Adelaide, Adelaide, Australia.

Cui HY, Hu FL, FangZS, Niu JY. 2015. Effects of irrigation amount and irrigation period on water requirement and yield of flax. Journal of Nuclear Agricultural Sciences, 29: 812– 819.

Currie DR. 2006. Soil physical degradation due to drip irrigation in vineyards: Evidences and implications. PhD Thesis, The University of Adelaide, Adelaide, Australia, 118 p. Available at: https://digital.library.adelaide.edu.au/dspace/bitstream/2440/ 58642/9/01front.pdf. (12/05/2018).

Deshmukh G, Hardaha MK. 2014. Effects of irrigation and fertigation scheduling under drip irrigation in papaya. J. Agric. Search., 1(4): 216-220.

El-Hendawy SE, Hokam EM, Schmidhalter U. 2008. Drip irrigation frequency: the effects and their interaction with nitrogen fertilization on sandy soil water distribution, maize yield and water use efficiency under Egyptian conditions. J. Agron. Crop Sci., 194: 180-192.

El-Meseery AA. 2003. Effects of different drip irrigation systems on maize yield in sandy soil. In Proc. 11th Annual Conf. Society MISR of Agriculture Engineering Role in Reducing Losses and Maximizing Production, Cairo, Egypt, 2003. MISR J. Agric, 576-594.

Ezekiel O, Igbadun HE, Mudiare OJ, Oyebode MA. 2017. Development of deficit irrigation for maize crop under drip irrigation in Samaru-Nigeria. Agricultural Engineering International: CIGR Journal, 19(1): 94-107.

Fasina AS, Aruleba JO, Omolayo FO, Omotoso SO, Shittu OS, Okusami TA. 2005. Properties and classification of five soils formed on granitic parent materials of Humid southwest, Nigeria. Nigerian Journal of Soil Science, 15(2): 21-29.

Fiebig A, Dodd IC. 2016. Inhibition of tomato shoot growth by over-irrigation is linked to nitrogen deficiency and ethylene. Physiol. Plant., 156: 70–83.

Ghezzehei TA, Or D. 2000. Dynamics of soil aggregates coalescence governed by capillary and rheological processes. Water Resources Research 36(2): 367-379.

Ibrahim MM, El-Baroudy AA, Taha AM. 2016. Irrigation and fertigation scheduling under drip irrigation for maize crop in sandy soil. Int. Agrophysics, 30: 47-55. Doi: 10.1515/intag2015-0071.

Igbadun HE. 2012. Impacts of methods of administering growthstage deficit irrigation on yield and soil water balance of a maize crop. Nigerian Journal of Basic and Applied Science, 20(4): 357–367.

Hamblin AP. 1985. The influence of soil structure on watermovement, crop root-growth, and water-uptake. Advances in Agronomy, 38: 95-158.

Kara T, Biber C. 2008. Irrigation frequencies and corn (Zea mays L.) yield relation in Northern Turkey. Pakistan Journal of Biological Sciences, 11(1): 123-126.

Kuscu H, Demir AO. 2013. Yield and water use efficiency of maize under deficit irrigation regimes in a sub-humid climate. Philippine Agricultural Scientist, 96(1): 32-41.

Kuscu H, Karasu A, Oz M, Demir AO. 2013. Effect of irrigation amounts applied with drip irrigation on maize evapotranspiration, yield, water use efficiency and net returns in a sub-humid climate. Turkish Journal of Field Crops 18(1): 13-19.

Liu J, Pattey E. 2010. Retrieval of leaf area index from top-ofcanopy digital photography over agricultural crops. Agricultural and Forestry Meteorology, 150: 1485-1490.

Meshkat M, Warner RC, Workman SR. 2000. Evaporation reduction potential in an undisturbed soil irrigated with surface drip and sand tube irrigation. Trans. ASAE., 43(1): 79-86.

Muhumed MA, Jusop S, Sung CTB, Wahab EM, Panhwar Q. 2014. Effects of drip irrigation frequency, fertilizer sources and their interaction on the dry matter and yield components of sweet corn. Australian Journal of Crop Science, 8(2): 223- 231.

Ne Smith DS, Ritchie JT. 1992. Short and long-term responses of corn to a pre-anthesis soil water deficit. Agron. J., 84: 107- 113.

Payero JO, Steven M, Irmak S, Tarkalson DD. 2006. Yield response of corn to deficit irrigation in a semi-arid climate. Agric. Water Manage., 94: 895-908. Reddy SR. 2006. Agronomy of field crops. 2 nd Ed. Kalyani Publishers, India.

Reichert JM, Suzuki LEAS, Reinert DJ, Horn R, Hakansson I. 2009. References bulk density and critical degree-ofcompactness for no-till crop production in subtropical highly weathered soils. Soil Till. Res., 102: 242-254.

Ritchie SW, Hanway JJ, Benson GO. 1986. How a corn plant develops. Special Report No. 48. Iowa State University of Science and Technology Cooperative Extension Service Ames, Iowa, USA, 24 pp.

Sampathkumar T, Pandian BJ. 2010. Effect of fertigation frequencies and levels on growth and yield of maize. Madras Agricultural Journal, 97(1-7): 245-248.

Saxena MC, Singh Y. 1965. A note on leaf area estimation of intact maize leaves. Indian Journal of Agronomy, 10: 437- 439.

Sezen SM, Yazar A, Eker S. 2007. Effect of drip irrigation regimes on yield and quality of field-grown bell pepper. In: Lamaddalena, N., Bogliotti, C., Todorovic, M., Scardigno, A. (eds.), Water saving in Mediterranean agriculture and future research needs. Options Méditerranéennes. Série B. Etudes et Recherches 1(56): 261-276.

Shariot-Ullah M, Mojid MA, Tabriz SS, Acharjee TK, Adham AKM. 2013. Growth and yield of three hybrid of maize varieties under different irrigation levels. Journal of Agric. Tech., 9(7): 1749-1758.

Soil Survey Staff (SSS) 2014. Keys to Soil Taxonomy. 12th Edition, USDA-Natural Resource Conservation Service, Washington CD, 372 pp.

SPAW. 2020. Soil water characteristics, version 6.02.74, USA) available at http://hydrolab.arsusda.gov/soilwater/index.htm.

Stone PJ, Wilson DR, Jamieson PD, Gillespie. RN. 2001. Water deficit effects on sweet corn I: water use, radiation use efficiency, growth, and yield. Aust. J. Agric. Res., 52: 103- 113.

USDA. 2011. Grain: World markets and trade. Foreign Agriculture Service, Circular Series FG 09-11. Foreign Agricultural Service, United States Department of Agriculture, http:// www.fas.usda.gov/psdonline/circulars/ grain.pdf

Wang FX, Kang Y, Liu. SP. 2006. Effects of drip irrigation frequency on soil wetting pattern and potato growth in North China Plain. Agricultural Water Management, 79(3): 248- 264.

Young IM. 1998. Biophysical interactions at the root-soil interface: a review. Journal of Agricultural Science, 130: 1-7.

Zhang YH, Zhang Q, Xu XX, Li JP, Wang B, Zhou SL et al. 2016. Optimal irrigation frequency and nitrogen application rate improving yield formation and water utilization in winter wheat under micro-sprinkling condition. Transactions of the CSAE, 32: 88-95.

Zhang L, Yun J, Wang HB, Tang R. 2018. Effects of different irrigation treatments on growth characteristics and water use efficiency of maize. Journal of Irrigation and Drainage 37: 24-29.