Effects of Regulated Deficit Irrigation Regime on Vegetative and Pomological Characteristics and Yield of Table Olive Konservolia Cultivar in Field Condition

Gholami, Rahmatollah; Hadjiamiri, Aboalmahsan; Najafi, Marzaban

doi:10.22055/ppd.2019.22905.1501

Document Type : Research Paper

Authors

¹ Associate Professor, Crop and Horticultural Science Research Department, Kermanshah Agricultural and Natural Resources Research and Education Center, AREEO, Kermanshah, Iran

² Instrcutor, Crop and Horticultural Science Research Department, Kermanshah Agricultural and Natural Resources Research and Education Center, AREEO, Kermanshah, Iran

³ Expert, Crop and Horticultural Science Research Department, Kermanshah Agricultural and Natural Resources Research and Education Center, AREEO, Kermanshah, Iran

https://doi.org/10.22055/ppd.2019.22905.1501

Abstract

Abstract

Background and Objectives
Olive (Olea europaea L.) is one of the every green trees that tolerance to Drought. Olive is an economically important species of the Mediterranean area, so understanding the mechanisms by which olive plants face drought stress under environmental conditions is essential for the improvement of olive yield and oil quality. Olive (Olea europaea L.) is one of the fruit trees which become important in the Iranian fruit industry at the near future. It seems that olive tree has potential for resistance to drought conditions of semi-arid regions of Iran. There is a high production potential for olive tree in many regions of Iran. Regulated deficit irrigation is an optimizing strategy under which crops are allowed to sustain some degree of water deficit and yield reduction. During regulated deficit irrigation the crop is exposed to certain level of water stress either during a particular period or throughout the growing season. The main objective deficit irrigation of is to increase water use efficiency (WUE) of the crop by eliminating irrigations that have little impact on yield, and to improve control of vegetative growth (improve fruit size and quality). The resulting yield reduction may be small compared with the benefits gained through diverting the saved water to irrigate other crops for which water would normally be insufficient under conventional irrigation practices. This study was aimed to investigate the effect of regulated deficit irrigation regime on vegetative and pomological characteristics and yield of table olive konservolia cultivar in field condition.

Materials and Methods
This experiment was conducted in Dallaho Olive Research Station (Geographical characters was longitude of 45˚, 51΄ E and latitude of 34˚, 30΄ N and the height of sea level 581m) located in Kermanshah province. An experiment was used based on a randomized complete block design with three replications. Adult table olive Konservolia cultivar was uesd. Each experiment unit consists of Three trees. Vegetative and reproductive traits were evaluated according to I.O.O.C. descriptors. Six irrigation regimes including of full irrigation (as control), regulated deficit irrigation (100% of full irrigation during growing season plus 25% irrigation during pit hardening, regulated deficit irrigation (100% of full irrigation during growing season plus 75% irrigation from Start pit hardening to harvesting), irrigation in three stage (before flowering, pit hardening and before Harvesting , 60% of full irrigation (continuous deficit irrigation) and no irrigation (Rainfed). To elevate the effect of irrigation regimes, some growth vegetative traits measured at the end of growth season including current-season shoot growth and current-season shoot diameter as well as some fruit traits including fruit and oil yield, fruit weight, fruit length and diameter, pulp fresh and dry weight, fruit moisture percent, pulp percent were measured. Collected data were analyzed with SAS program.

Results
Obtained results showed that the highest fruit yield, oil yield, fruit weight, fruit diameter, pulp fresh and dry weight, pulp percent were observed at full irrigation and regulated deficit irrigation (100% of full irrigation during growing season plus 25% irrigation during pit hardening, but the lowest one found at Rainfed. There was no significant difference between deficit irrigation in three stage and 60% of full irrigation (continuous deficit irrigation) in fruit yield, oil yield, fruit weight, fruit diameter, pulp fresh and dry weight. The water use efficiency of fruit yield of T₄ and T₂ was higher than 100ETc and other treatments. Overall, the results showed that RDI during fruit pit hardening could increased water use efficiency, whitout reduce fruit yield, oil yield, fruit weight, fruit diameter and pulp fresh and dry weight.

Discussion
In the arid and semi arid as well as sub-tropical regions, water shortage is a normal phenomenon and seriously limits the agricultural potential.Therefore, under irrigation or rain-fed conditions, it is important for the available water to be used in the most efficient way. Regulated deficit irrigation is an optimizing strategy under which crops are allowed to sustain some degree of water deficit and yield reduction. During regulated deficit irrigation the crop is exposed to certain level of water stress either during a particular period or throughout the growing season. The main objective deficit irrigation of is to increase water use efficiency (WUE) of the crop by eliminating irrigations that have little impact on yield, and to improve control of vegetative growth (improve fruit size and quality). According to the results of this research, it can be concluded thatthat RDI during fruit pit hardening could increased water use efficiency, whitout reduce fruit yield, oil yield, fruit weight, fruit diameter, pulp fresh and dry weight.

Keywords

Main Subjects

References

References

Ahmadipour, S. and Arji, I. (2012). Evaluation on "Zard" and "Roghani" olive cultivars responses in different region of Kermanshah. Plant Productions, 35(1), 113-126. [In Farsi]

Arzani, K. and Arji, I. (2000). The effect of water stress and deficit irrigation on young potted olive cv. Local-RoghaniRoodbar. Acta Horticulture, 537, 879-885.

Bacelar, E. A., Moutinho-Pereira, J. M., Goncalves, B. C., Lopes, J. I. and Correia, C. M. (2009). Physiological responses of different olive genotypes to drought conditions. Acta Physiologiae Plantarum, 31(3), 611-621.

Berenguer, M. M. J., Gratten, S., Conne, J., Polito, .V. and Vossen, P. (2002). Optimizing olive oil production and quality through irrigation management, university of California cooperative Extension and UC Davis. Retrieved fromhttp/www.cesonoma,ucdavis.edu/files/51774-pdf.

Boughalleb, F. and Mhamdi, M. (2011). Possible involvement of proline and the antioxidant defense systems in drought tolerance of three olive cultivars grown under increasing water deficit regimes. Agricultural Journal, 6(6), 371-391.

Caruso, G., Gucci, R., Urbani, S., Esposto, S., Taticchi, A., Di Maio, I., Selvaggini, R. and Servili, M. (2014). Effect of different irrigation volumes during fruit development on quality of virgin olive oil of cv. Frantoio. Agricultural Water Management, 134, 94-103.

Chai, Q., Gan, Y., Zhao, C., Xu, H. L., Waskom, R. M., Niu, Y. and Siddique, K. H. M. (2015). Regulated deficit irrigation for crop production under drought stress. Agronomy for Sustainable Development, 36(3), 1-21.

Chalmers, D. J., Burge, G., Jerie, P. H. and Mitchell, P. D. (1986) .The mechanism of regulation of Bartlett Pear fruit and vegetative growth by irrigation withholding and regulated deficit irrigation. Journal of the American Society for Horticultural Science,111(6), 904-907.

Correa-Tedesco, G., Rousseaux, M. C and Searles, P. S. (2010). Plant growth and yield responses in olive (Olea europaea L.) to different irrigation levels in an arid region of Argentina. Agricultural Water Management, 97(11), 1829-1837.

Costa, J. M., Ortuno, M. F. and Chaves, M. M. (2009). Deficit irrigation as a strategy to save water: Physiologyand potential application to horticulture. Journal of Integrative Plant Biology, 49(10), 1421-1434.

D’ Andria, R., Morelli, G., Patiumi, M and Fontanazza, G. (2000). Irrigation regime affects yield and oil quality of olive trees. 4^th International Symposium on olive Growing, Valenzano (Bari) Italy.

Dell’Amico, J., Moriana, A., Corell, M., Giron, I. F., Morales, D., Torrecillas, A. and Moreno, F. (2012). Low water stress conditions in table olive trees (Olea europaea L.) during pit hardening produced a different response of fruit and leaf water relations. Agricultural Water Management, 114, 11-17.

FAO. (2008). Food and agriculture organization. Retrieved fromhttp/www.fao.org/nr/water/eto.html.

Fereres, E. and Soriano, M. A. (2007). Deficit irrigation for reducing agricultural water use. Journal of Experimental Botany, 58, 147-159.

Gholami, R. and Gholami, H. (2019). The effect of drought stress on some vegetative and physiological characteristics of superior local olive genotypes (Olea europaea L.) in pot conditions. Plant Productions, 41(4), 15-29. [In Farsi]

Giron, I.F., Corell, M., Galindo, A., Torrecillas, E., Morales, D., Dell’Amico, J., Torrecillas, F., Moreno, A. and Moriana, A. (2015). Changes in the physiological response between leaves and fruits during a moderate water stress in table olive trees. Agricultural Water Management, 148, 280-286.

I.O.O.C. (2002a). Methodology for the primary characterization of olive varieties. Project on conservation, characterization, collection of Genetic Resources in olive, International Olive Oil Council, Madrid, Spain.

I.O.O.C. (2002b). Methodology for the secondary characterization (agronomic, phonological, pomological and oil quality) of olive varieties held in collection. Project on conservation, characterization, collection of Genetic Resources in olive, International Olive Oil Council, Madrid, Spain.

Iniesta, F., Testi, L., Orgaz, F. and Villalobos, F. J. (2009).The effects of regulated and continuous deficit irrigation on the water use, growth and yield of olive trees. European Journal of Agronomy, 30, 258-265.

Jacobsen, S. E, Jensen C. R, Liu.F. (2012). Improving crop production in the arid Mediterranean climate. Field Crops Research, 128, 34-47.

Jafari, A. and Mahlooji, M. (2005). future strategy in retrospect, the lessons of the recent drought in Isfahan. Journal of Drought and Agricultural Drought, 17, 34-30. [In Farsi]

Kheirabi, J., Tavakoli A., Entesari M. and Salamat A. (1996). Deficit irrigation guidelines. The Iranian National Committee on Irrigation and Drainage, Tehran. [In Farsi]

Li, S. H., Huguet, J. G., Schoch, P. G. and Orlando, P. (1989). Respone of peach tree growth and cropping to soil water deficit at various phonological stages of fruit development. Journal of Horticulture Science,64(5), 541-552.

Mezghani, M. A., Charfi, C. M., Gouiaa, M. and Labidi, F. (2012).Vegetative and reproductive behaviour of some olive tree varieties (Olea europaea L.) under deficit irrigation regimes in semi-arid conditions of Central Tunisia. Scientia Horticulturae, 146, 143-152.

Moriana, A., Perez-Lopez, D., Prietoc, M.H., Ramirez-Santa-Pau, M. and Perez-Rodriguez, J. M. (2012). Midday stem water potential as a useful tool for estimating irrigation requirements in olive trees. Agricultural Water Management, 112, 43-54.

Naor, A. (2006). Irrigation scheduling and evaluation of tree water status in deciduous orchards. Horticultural Reviews, 32 111-165.

Perez-Lpez, D., Ribas, F., Moriana, A., Olmedilla, N. and de Juan, A. (2007). The effect of irrigation schedules on the water relations and growth of a young olive (Olea europaea L.) orchard. Agricultural Water Management, 89(3), 297-304.

Rapoport, H. F. and Costagli, G. (2004).The effect of water deficit during early fruit development on olive fruit morphogenesis. Journal of the American Society for Horticultural Science, 129(1), 121-127.

Rosecrance, R. C., Krueger, W. H., Milliron, L., Bloese, J., Garcia, C. and Mori, B. (2015). Moderate regulated deficit irrigation can increase olive oil yields and decrease tree growth in super high density Arbequina olive orchards. Scientia Horticulturae, 19(16), 75-82.

Rouhi, V., Samson, R., Lemeur, R. and Van Damme, P. (2007). Photosynthetic gas exchange characteristics in three different almond species during drought stress and subsequent recovery. Environmental and Experimental Botany, 59(2), 117-129.

Ruiz-Sanchez, M.C., Domingo, R. and Castel, J. R. (2010). Review. Deficit irrigation in fruit trees and vines in Spain. Spanish Journal of Agricultural Research, 8(2), 5-20.

Sofo, A., Manfreda, S., Fiorentino, M., Dichio, B. and Xiloyannis, C. (2008). The olive tree: A paradigm for drought tolerance in Mediterranean climates. Hydrology and Earth System Sciences, 12(1), 293-301.

Tognetti, R., D., Andria, R., Lavivi, A. and Morelli, G. (2006). The effect of deficit irrigation on crop yield and development of olea europaea L., (cvs Frantoio and Leccino). European Journal of Agronomy, 25(4), 356-364.

© 2019 by the authors. Licensee SCU, Ahvaz, Iran. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-Non Commercial 4.0 International (CC BY-NC 4.0 license) (http://creativecommons.org/licenses/by-nc/4.0/)

Effects of Regulated Deficit Irrigation Regime on Vegetative and Pomological Characteristics and Yield of Table Olive Konservolia Cultivar in Field Condition

References

References

Volume 42, Issue 4December 2019Pages 575-585

Volume 42, Issue 4
December 2019
Pages 575-585