[1].Korti, A., Amara, D.G., Chemsa, A.E. and Gheraissa, N., 2025. A Review on General Description of Leucaena Leucocephala (Lam.) De Wit. Gradiva, 64(6), pp.101-113
[2].Casanova-Lugo, F., Solorio-Sánchez, F.J., Ramírez-Avilés, L., Caamal-Maldonado, J.A. and Ku-Vera, J.C., 2014. Forage yield and quality of Leucaena leucocephala and Guazuma ulmifolia in tropical silvopastoral systems. Tropical Grasslands-Forrajes Tropicales, 2(1), pp.24-26..
[3].Singh, A. 2012. Effect of spatial distribution on the growth performance of Leucaena leucocephala planted on coal mine spoil. Bulletin of Environment, Pharmacology and Life Sciences, 1, 55-57.
[4].Sharma, S., Naithani, R., Varghese, B., Keshavkant, S. and Naithani, S. 2008. Effect of hot-water treatment on seed germination of some fast growing tropical tree species. Journal of Tropical Forestry, 24, 49-53.
[5].Rasheed, F., Gondal, A., Kudus, K.A., Zafar, Z., Nawaz, M.F., Khan, W.R., Abdullah, M., Ibrahim, F.H., Depardieu, C., Pazi, A.M.M. and Anjum, K., 2021. Effects of soil water deficit on three tree species of the arid environment: Variations in growth, physiology, and antioxidant enzyme activities. Sustainability, 13(6), p.3336.
[6].Arabi, D.A., Adlan, M.I. and Mohamed, O.A., 2025. The Effect of Light Intensity and Watering Interval on Growth and Development of Three Legume Tree Species Seedlings. Nile Journal for Agricultural Sciences, 10(1), pp.17-33.
[7].Rajarajan, K. and Handa, A. 2020. Drought stress responses in seedlings of three multipurpose agroforestry trees species of central India. Range Management and Agroforestry, 41, 182-187.
[8].Tadros, M. J., Al-Mefleh, N. K. and Chandler, P. 2012b. Morphology, productivity and forage quality of Leucaena leucocephala as influenced by irrigation under field conditions. Agroforestry systems, 86, 73-81.
[9].Oweis, T. and Hachum, A. 2006. Water harvesting and supplemental irrigation for improved water productivity of dry farming systems in West Asia and North Africa. Agricultural water management, 80, 57-73.
[10]. Bainbridge, D. A. 2012. A guide for desert and dryland restoration: new hope for arid lands, Island press.
[11]. Bremner, J. M. and Mulvaney, C. 1982. Nitrogen—total. Methods of soil analysis: part 2 chemical and microbiological properties, 9, 595-624.
[12]. Jones, J. B. 2001. Laboratory guide for conducting soil tests and plant analysis, CRC press.
[13]. Qadir, S.A., Khursheed, M.Q. and Huyop, F.Z., 2016. Effect of Drought Stress on Morphology, Growth and Yield of Six Bread Wheat (Triticum aestivum L.) Cultivars. ZANCO Journal of Pure and Applied Sciences, 28(3), pp.37-48.
[14]. Ahmad, S., Ali, H., Ur Rehman, A., Khan, R. J. Z., Ahmad, W., Fatima, Z., Abbas, G., Irfan, M., Ali, H. and Khan, M. A. 2015. Measuring leaf area of winter cereals by different techniques: A comparison. Pak. J. Life Soc. Sci, 13, 117-125.
[15]. Sherzad, O.H., Zaki, H.M., Hazandy, A.H. and Azani, A.M., 2017. Effect of different shade periods on Neobalanocarpus heimii seedlings biomass and leaf morphology. Journal of Tropical Forest Science, pp.457-464.
[16]. Hamad, S. O. 2023. Effect of Different Irrigation Periods and Mulching on Growth of Paulownia tomentosa (Thunb.) Steud. Seedlings. Zanco Journal of Pure and Applied Sciences, 35, 195-207.
[17]. Magomya, A., Kubmarawa, D., Ndahi, J. and Yebpella, G. 2014. Determination of plant proteins via the Kjeldahl method and amino acid analysis: A comparative study. Int. J. Sci. Technol. Res, 3, 68-72.
[18]. Karim, S.A., Qadir, S.A. and Sabr, H.A., 2020. Study some of morphological and physiological traits of Kurrajong Brachychiton populneus (Schott and Endl.) seedlings planted under water stress conditions. Basrah Journal of Agricultural Sciences, 33(1), pp.213-220. https://doi.org/10.37077/25200860.2020.33.1.16.
[19]. Hubbard, R.M., Stape, J., Ryan, M.G., Almeida, A.C. and Rojas, J., 2010. Effects of irrigation on water use and water use efficiency in two fast growing Eucalyptus plantations. Forest Ecology and Management, 259(9), pp.1714-1721.doi: https://doi.org/10.1016/j.foreco.2009.10.028.
[20]. Duncan, D.B., 1955 – Multiple range and multiple F tests.biometrics, 11(1), pp.1-42.doi: https://doi.org/10-2307/3001478.
[21]. Rahman, M.H., Begum, S., Nugroho, W.D., Nakaba, S. and Funada, R., 2022. The effects of watering on cambial activity in the stems of evergreen hardwood (Samanea saman) during the pre-monsoon season in subtropical Bangladesh. Journal of Wood Science, 68(1), p.47.
[22]. Kayode, J. & Tedela, P. 2005. Effect of Irrigation Frequency on Germination, Root and Shoot Yields of Leucaena leucocephala. Pakistan Journal of Forestry, 55, 1.
[23]. Singh, G. and Rathod, T. 2010. Effects of quantity and frequency of irrigation on growth and nutrient uptake in Acacia nilotica seedlings in Indian dry zone. Archives of Agronomy and Soil Science, 56, 311-323.
[24]. Rostami, A. A. and Rahemi, M. 2013. Responses of caprifig genotypes to water stress and recovery. Journal of Biological and Environmental Sciences, 7(21), pp. 131-139.
[25]. Chaves, M. M., Pereira, J. S., Maroco, J., Rodrigues, M. L., Ricardo, C. P. P., Osório, M. L., Carvalho, I., Faria, T. and Pinheiro, C. 2002. How plants cope with water stress in the field? Photosynthesis and growth. Annals of botany, 89, 907.
[26]. Martínez De Azagra Paredes, A., Del Río San José, J., Reque Kilchenmann, J., Diez Hernández, J. M. and Sanz Ronda, F. J. 2022. Methods for watering seedlings in arid zones. Forests, 13, 351.
[27]. Chaves, M.M., Santos, T.P., Souza, C.D., Ortuño, M.F., Rodrigues, M.L., Lopes, C.M., Maroco, J.P. and Pereira, J.S., 2007. Deficit irrigation in grapevine improves water‐use efficiency while controlling vigour and production quality. Annals of applied biology, 150(2), pp.237-252.
[28]. Romero, P., Dodd, I.C. and Martinez-Cutillas, A., 2012. Contrasting physiological effects of partial root zone drying in field-grown grapevine (Vitis vinifera L. cv. Monastrell) according to total soil water availability. Journal of experimental botany, 63(11), pp.4071-4083.
[29]. Yang, P., Wu, L., Cheng, M., Fan, J., Li, S., Wang, H. and Qian, L., 2023. Review on drip irrigation: impact on crop yield, quality, and water productivity in China. Water, 15(9), p.1733.
[30]. Singh, N. T. 2005. Irrigation and soil salinity in the Indian subcontinent: past and present, Lehigh University Press
[31]. Hsiao, T.C. (2000) ‘Leaf and root growth in relation to water status’, HortScience, 35(6), pp. 1051–1058.
[32]. Padilla, F.M. & Pugnaire, F.I. (2007) ‘Rooting depth and soil moisture control Mediterranean woody seedling survival during drought’, Functional Ecology, 21(3), pp. 489–495.
[33]. Kozlowski, T.T. and Pallardy, S.G., 2002. Acclimation and adaptive responses of woody plants to environmental stresses. The botanical review, 68(2), pp.270-334.
[34]. Bauer, H., Ache, P., Lautner, S., Fromm, J., Hartung, W., Al-Rasheid, K. A., Sonnewald, S., Sonnewald, U., Kneitz, S. and Lachmann, N. 2013. The stomatal response to reduced relative humidity requires guard cell-autonomous ABA synthesis. Current Biology, 23, 53-57.
[35]. Conesa, M., De La Rosa, J., Domingo, R., Banon, S. and Pérez-Pastor, A. 2016. Changes induced by water stress on water relations, stomatal behaviour and morphology of table grapes (cv. Crimson Seedless) grown in pots. Scientia Horticulturae, 202, 9-16.
[36]. Chaves, M. M., Maroco, J. P. and Pereira, J. S. 2003. Understanding plant responses to drought—from genes to the whole plant. Functional plant biology, 30, 239-264.
[37]. Pallardy, S. G. 2010. Physiology of woody plants, academic press.
[38]. Gorlapalli, A., Kallakuri, S., Sreekanth, P. D., Patil, R., Bandumula, N., Ondrasek, G., Admala, M., Gireesh, C., Anantha, M. S. and Parmar, B. 2022. Characterization and prediction of water stress using time series and artificial intelligence models. Sustainability, 14, 6690.
[39]. Hossain, S., Lixue, W., Uddin, M. E., Dan, L., Haisheng, L. and Siping, L. 2017. Contemporary perspective of drip Irrigation: A review of water saving crop production. Asian Research Journal of Agriculture, 3, 1-22.
[40]. Lopez Laphitz, R.M., Arana, M.V., Varela, S.A., Becker, L.A., Soliani, C., Azpilicueta, M.M., Marchelli, P. and Bellora, N., 2024. Transcriptomic responses to drought stress in the Patagonian southern beech Nothofagus alpina. Ecological Processes, 13(1), p.34.
[41]. Al-Mefleh, N. K. and Tadros, M. J. 2010. Influence of water quantity on the yield, water use efficiency, and plant water relations of Leucaena leucocephala in arid and semi arid environment using drip irrigation system. African Journal of Agricultural Research, 5, 1917-1924.
[42]. Jackson, R.B., Canadell, J., Ehleringer, J.R., Mooney, H.A., Sala, O.E. and Schulze, E.D., 1996. A global analysis of root distributions for terrestrial biomes. Oecologia, 108(3), pp.389-411. https://doi.org/10.1007/BF00333714
[43]. Farahnak, M., Mitsuyasu, K., Hishi, T., Katayama, A., Chiwa, M., Jeong, S., Otsuki, K., Sadeghi, S.M.M. and Kume, A., 2020. Relationship between very fine root distribution and soil water content in pre-and post-harvest areas of two coniferous tree species. Forests, 11(11), p.1227.
[44]. Colmer, T.D. and Voesenek, L.A.C.J., 2009. Flooding tolerance: suites of plant traits in variable environments. Functional Plant Biology, 36(8), pp.665-681.
[45]. Bailey-Serres, J. and Voesenek, L.A.C.J., 2008. Flooding stress: acclimations and genetic diversity. Annu. Rev. Plant Biol., 59(1), pp.313-339.
[46]. Bhattarai, S.P., Pendergast, L. and Midmore, D.J., 2006. Root aeration improves yield and water use efficiency of tomato in heavy clay and saline soils. Scientia horticulturae, 108(3), pp.278-288.
[47]. Pendergast, L., Bhattarai, S.P. and Midmore, D.J., 2013. Benefits of oxygation of subsurface drip-irrigation water for cotton in a Vertosol. Crop and Pasture Science, 64(12), pp.1171-1181.
[48]. Camp, C.R., Lamm, F.R., Evans, R.G. and Phene, C.J., 2000, November. Subsurface drip irrigation–Past, present and future. In Proc. Fourth Decennial Nat’l Irrigation Symp., Nov (pp. 14-16).
[49]. Byambadorj, S.O., Park, B.B., Lkhagvasuren, S., Tsedensodnom, E., Byambasuren, O., Khajid, A., Chiatante, D. and Nyam-Osor, B., 2023. Influence of irrigation on biomass partitioning in above-and belowground organs of trees planted in desert sites of Mongolia. Forests, 15(1), p.46.
[50]. Byambadorj, S.-O., Park, B. B., Hernandez, J. O., Dulamsuren, N., Sainbuyan, Z., Altantugs, O., Sharavdorj, K., Seong, I. K. and Batkhuu, N.-O. 2021. Optimal irrigation regime for woody species potentially suitable for effective and sustainable afforestation in the desert region of Mongolia. Land, 10, 212.
[51]. Shaheen, J. 2017. Modeling water and fertilizer use in wick irrigation system for smallholder greenhouse crop production. Perpustakaan Sultan Abdul Samad UPM, 1-26.
[52]. Susiluoto, S. and Berninger, F. 2007. Interactions between morphological and physiological drought responses in Eucalyptus microtheca. Silva Fennica, 41(2),p.221.
[53]. Zang, U., Goisser, M., Häberle, K. H., Matyssek, R., Matzner, E. and Borken, W. 2014. Effects of drought stress on photosynthesis, rhizosphere respiration, and fine‐root characteristics of beech saplings: A rhizotron field study. Journal of plant nutrition and soil science, 177(2), pp.168-177.
[54]. Deligoz, A., Bayar, E. and Yazici, N. 2016. Responses of growth, water relations and compatible solutes contents to repeated drought stress in Cedrus libani. Fresen Environ Bull, 25, 3760-3767.
[55]. Deligöz, A. and Bayar, E. 2018. Drought stress responses of seedlings of two oak species (Quercus cerris and Quercus robur). Turkish Journal of Agriculture and Forestry, 42(2), pp.114-123.
[56]. Grossnickle, S.C. and MacDonald, J.E., 2018. Seedling quality: history, application, and plant attributes. Forests, 9(5), p.283.
[57]. Wu, M., Zhang, W., Ma, C. and Zhou, J. 2013. Changes in morphological, physiological, and biochemical responses to different levels of drought stress in Chinese cork oak (Quercus variabilis Bl.) seedlings. Russian journal of plant physiology, 60, 681-692.
[58]. Poorter, H., Niklas, K.J., Reich, P.B., Oleksyn, J., Poot, P. and Mommer, L., 2012. Biomass allocation to leaves, stems and roots: meta‐analyses of interspecific variation and environmental control. New phytologist, 193(1), pp.30-50.
[59]. Mainhart, D.E., Christoffersen, B.O., Thompson, R.A., Reemts, C.M. and Fierro-Cabo, A., 2024. Preparing for the Worst: Enhancing Seedling Traits to Reduce Transplant Shock in Semi-Arid Regions. Forests, 15(9), p.1607.
[60]. Huang, H., Shi, Y., Luo, A., Xiao, Y., Liang, J. and He, Z. 2025. Effects of irrigation frequency on root growth, nutrients accumulation, yield, and water use efficiency of Panax notoginseng under micro-sprinkler irrigation. Frontiers in Plant Science, 16, 1549506.
[61]. Scagel, C.F., Bi, G., Fuchigami, L.H. and Regan, R.P., 2011. Effects of irrigation frequency and nitrogen fertilizer rate on water stress, nitrogen uptake, and plant growth of container-grown rhododendron. HortScience, 46(12), pp.1598-1603.
[62]. Zhang, R., Nie, L., Huang, M., Yang, H., Shi, C., Wei, Y., Song, L., Zhu, J., Bo, H. and Wang, J. 2022. Effects of irrigation and nitrogen application on soil nutrients in triploid Populus tomentosa stands. Forests, 13, 1046.
[63]. de Sousa, A., Ratke, R.F., Viera, J.W.P., de Souza, F.V., Zuffo, A.M. and Aguilera, J.G., 2021. Produção de mudas de Leucaena leucocephala com uso de fertilizante mineral e organomineral. Research, Society and Development, 10(2), pp.e28710212095-e28710212095.
[64]. He, Y., Lin, X., Wang, L., Ma, X., Fang, L. and Xia, Z. 2023. Effects of long-term irrigation on soil phosphorus fractions and microbial communities in Populus euphratica plantations. Forestry Research, 3, 17.
[65]. Marschner, H. 2012. Marschner's mineral nutrition of higher plants, Academic press.
[66]. Holz, M., Zarebanadkouki, M., Benard, P., Hoffmann, M. and Dubbert, M., 2024. Root and rhizosphere traits for enhanced water and nutrients uptake efficiency in dynamic environments. Frontiers in Plant Science, 15, p.1383373
[67]. Wang, H., Yan, Z., Ju, X., Song, X., Zhang, J., Li, S. and Zhu-Barker, X., 2023. Quantifying nitrous oxide production rates from nitrification and denitrification under various moisture conditions in agricultural soils: Laboratory study and literature synthesis. Frontiers in Microbiology, 13, p.1110151.
[68]. Lambers, H., Shane, M.W., Cramer, M.D., Pearse, S.J. and Veneklaas, E.J., 2006. Root structure and functioning for efficient acquisition of phosphorus: matching morphological and physiological traits. Annals of botany, 98(4), pp.693-713.
[69]. Rutter, E.B. and Ruiz Diaz, D.A., 2021. Evaluation of Soil Parameters After Long-Term Subsurface Drip Irrigation Under Minimum Tillage System. Kansas Agricultural Experiment Station Research Reports, 7(8), p.11.
[70]. Bitterlich, M., Jansa, J., Graefe, J., Pauwels, R., Sudová, R., Rydlová, J. and Püschel, D., 2024. Drought accentuates the role of mycorrhiza in phosphorus uptake, part II–The intraradical enzymatic response. Soil Biology and Biochemistry, 193.
[71]. Chtouki, M., Naciri, R. and Oukarroum, A., 2024. A review on phosphorus drip fertigation in the Mediterranean region: Fundamentals, current situation, challenges, and perspectives. Heliyon, 10(3).
[72]. Matimati, I., Verboom, G.A. and Cramer, M.D., 2014. Nitrogen regulation of transpiration controls mass-flow acquisition of nutrients. Journal of experimental botany, 65(1), pp.159-168.
[73]. Liu, Z., Long, K., Zeng, J., Zhang, Y., Shi, Q., Hui, B., Zhang, P., Papadakis, G. and Zhang, Q., 2024. Effects of Cyclic Aeration Subsurface Drip Irrigation on Greenhouse Tomato Quality and Water and Fertilizer Use Efficiency. Plants, 13(24), p.3559.
[74]. Yao, D., Yang, J., Jia, H., Zhou, Y., Lv, Q., Li, X., Zhang, H., Fesobi, P., Liu, H., Zhao,F.and Yu, K., 2023. Application fruit tree hole storage brick fertilizer is beneficial to increase the nitrogen utilization of grape under subsurface drip irrigation. Frontiers in Plant Science, 14, p.1259516.
[75]. Isyaku, M., Amans, E., Falaki, A., Mahmoud, M., Sharifai, A. and Muhammad, A. 2010. Effect of water harvesting methods, nitrogen-phosphorus fertilizer and variety on leaf tissue n, and p, and soil moisture content of date palm (phonix dactylifera l.). Bayero Journal of Pure and Applied Sciences, 3.
[76]. Yige, C., Fangqing, C., Lei, L. & Shunbo, Z., 2012. Physiological responses of Leucaena leucocephala seedlings to drought stress. Procedia Engineering, 28, pp.110–116. https://doi.org/10.1016/j.proeng.2012.01.690
[77]. Ashraf, M. & Harris, P.J.C., 2013. Photosynthesis under stressful environments: An overview. Photosynthetica, 51(2), pp.163–190. https://doi.org/10.1007/s11099-013-0021-6
[78]. Farooq, M., Wahid, A., Kobayashi, N., Fujita, D. & Basra, S.M.A., 2009. Plant drought stress: effects, mechanisms and management. Agronomy for Sustainable Development, 29(1), pp.185–212. https://doi.org/10.1051/agro:2008021
[79]. Taiz, L., Zeiger, E., Møller, I. M. and Murphy, A. 2015. Plant physiology and Development.
[80]. Zegada-Lizarazu, W., Zatta, A. and Monti, A., 2012. Water uptake efficiency and above-and belowground biomass development of sweet sorghum and maize under different water regimes. Plant and Soil, 351(1), pp.47-60.
[81]. Oliveira, C.E.D., Nascimento, A.A.D., Moura, J.M.D., Silva, M.L., Fernandes, C.N. and Silva, A.R.D., 2025. EFFECTS OF WATER REGIMES AND IRRIGATION FREQUENCIES ON COWPEA GROWTH. Engenharia Agrícola, 45(spe1), p.e20240181.https://doi.org/10.1590/1809-4430-Eng.Agric.v45nespe120240181/2025
[82]. Bhattarai, S.P., Midmore, D.J. and Pendergast, L., 2008. Yield, water-use efficiencies and root distribution of soybean, chickpea and pumpkin under different subsurface drip irrigation depths and oxygation treatments in vertisols. Irrigation science, 26(5), pp.439-450.
[83]. Li, L., Zhou, K., Yang, X., Su, X., Ding, P., Zhu, Y., Cao, F. and Han, J., 2025. Leaf nitrogen allocation to non-photosynthetic apparatus reduces mesophyll conductance under combined drought-salt stress in Ginkgo biloba. Frontiers in Plant Science, 16, p.1557412.
