Impacts of fertigation via surface and subsurface drip irrigation on growth rate, yield and flower quality of Zinnia elegans

Elhindi, Khalid; El-Hendawy, Salah; Abdel-Salam, Eslam; Elgorban, Abdallah; Ahmed, Mukhtar

doi:10.1590/1678-4499.176

ABSTRACT

Drip irrigation combined with split application of fertilizer nitrogen (N) dissolved in the irrigation water (i.e. drip fertigation) is commonly considered best management practice for water and nutrient efficiency. This research was conducted to study the influence of drip fertigation in combination with or without N fertilizers on vegetative growth, flowering quality, nutrients concentration in plants and soil fertility after the harvest of zinnia ( Zinnia elegans). A field experiment was conducted using a randomized complete block split plot design with two systems of drip irrigation (surface and subsurface drip irrigation) and 4 nitrogen rates (0, 30, 60, and 120 kg∙ha^–1) as the main and split plots, respectively. The results revealed that vegetative growth rate, flowering characteristics , plant chemical contents, plant uptake and available soil from N, P, K, Fe, Mn, and Zn of zinnia increased significantly with increasing N level up to 120 kg∙ha^–1. A similar trend was also found in the post-harvest soil fertility and nutrient uptake that approved the importance of drip fertigation with N fertilizers. Subsurface drip irrigation system was found to be more efficient than surface drip irrigation system to obtain maximum yield accompanied by the highest nutrients concentration in zinnia plants and soil fertility after harvest.

Key words:
available soil nutrients; irrigation system; sandy soil; yield attributes; Zinnia elegans

INTRODUCTION

Field water management practices are the most effective factors affecting crop yield particularly in irrigated agriculture in arid and semi-arid regions. Sandy soils are particularly critical for water management in irrigated agriculture because of their low water-holding capacity and low clay contents. The productivity of these soils is limited by high infiltration rate, high evaporation, low fertility level, low water-holding capacity and low organic matter content (Suganya and Sivasamy 2006Suganya, S. and Sivasamy, R. (2006). Moisture retention and cation exchange capacity of sandy soil as influenced by soil additives. Journal of Applied Sciences Researche, 2, 949-951.). The reasonable use of scarce water resources in Egypt is a top priority for agriculture. The pressure for using water in agriculture sector is increasing to create ways to improve water-use efficiency and take a full advantage of available water. Therefore, the adoption of modern irrigation techniques is needed to increase water-use efficiency. High water application efficiencies are often possible with drip irrigation, since there is reduced surface evaporation, less surface runoff, as well as minimal deep percolation (Jiusheng et al. 2003Jiusheng, L., Jianjun, Z. and Ren, L. (2003). Water and nitrogen distribution as affected by fertigation of ammonium nitrate from a point source. Irrigation Science, 22, 19-30. http://dx.doi.org/10.1007/s00271-003-0064-8.
http://dx.doi.org/10.1007/s00271-003-006... ). Furthermore, a drip irrigation system can easily be used for fertigation, through which crop nutrient requirements can be met accurately. The level of fertigation management for achieving high yields and crop quality appears to exceed what is found with other irrigation methods. There are several other advantages of fertigation through drip irrigation systems, as discussed by Burt et al. (1998)Burt, C. O., Connor, K. and Ruehr, T. (1998). Chemicals for fertigation; [accessed 2015 Oct. 21]. http://www.itrc.org/papers/pdf/chemicalsforfertigation.pdf
http://www.itrc.org/papers/pdf/chemicals... .

In recent years, there has been tremendous interest in applying fertilizer nutrients through the irrigation system (fertigation) as a source of providing nutrients to ornamental plants in Egypt. Drip offers the potential of efficient water delivery and complete flexibility with regard to N fertigation.

Urea is best suited to fertigation because it is relatively cheaper. However, a major concern associated with urea fertigation is soil acidification. Drip irrigation combined with application of N fertilizer dissolved in the irrigation water (i.e. drip fertigation) is considered an efficient strategy for water and nutrient application during crop production (Thompson et al. 2000Thompson, T. L., Doerge, T. A. and Godin, R. E. (2000). Nitrogen and water interactions in subsurface drip irrigated cauliflower. I. Plant response. Soil Science Society of America Journal, 64, 406-11.). This is because drip irrigation reduces surface evaporation and deep percolation, obtaining high water use efficiency, while fertigation is wonderfully suitable for regulating the induction, time and level of fertilizer N application, thereby increasing N use efficiency (Darwish et al. 2006Darwish, T. M., Atallah, T. W., Hajhasan, S. and Haidar, A. (2006). Nitrogen and water use efficiency of fertigated processing potato. Agriculture Water Management, 85, 95-104. http://dx.doi.org/10.1016/j.agwat.2006.03.012.
http://dx.doi.org/10.1016/j.agwat.2006.0... ). Some of these preference which are illustrate in literature (Asadi et al. 2002Asadi, M. E., Clemente, R. S., Gupta, A. D., Loof, R. and Hansen, G. K. (2002). Impacts of fertigations via sprinkler irrigation on nitrate leaching and corn yield in an acid-sulphate soil in Thailand. Agriculture Water Management, 52, 197-213. http://dx.doi.org/10.1016/S0378-3774(01)00136-6.
http://dx.doi.org/10.1016/S0378-3774(01)... ; Lesschen et al. 2011Lesschen, J. P., Velthof, G. L., Vries, D. E. W., and Kros, J. (2011). Differentiation of nitrous oxide emission factors for agricultural soils. Environmental. Pollution, 159, 3215-22. http://dx.doi.org/10.1016/j.envpol.2011.04.001.
http://dx.doi.org/10.1016/j.envpol.2011.... ; Abalos et al. 2014Abalos, D., Sanchez-Martin, L., Garcia-Torres, L., van Groenigen, J. W. and Vallejo, A. (2014). Management of irrigation frequency and nitrogen fertilization to mitigate GHG and NO emissions from drip-fertigated. Crop Sciences Environmental, 490, 880-888. http://dx.doi.org/10.1016/j.scitotenv.2014.05.065
http://dx.doi.org/10.1016/j.scitotenv.20... ) through timely nitrogen utilization, excellent uniformity of N function, losses of environmental contamination, movement of tested N into the rooting zone by irrigation water and losses of soil compressed and mechanical deterioration to the plant. Furthermore, Papadopoulos (2000)Papadopoulos, I. (2000). Fertigation: present and future prospects. In J. Ryan (Ed.), Plant nutrient management under pressurized irrigation systems in the Mediterranean Region (p. 232-245). Amman: ICARDA. reported that the fertigation of many plants under suppress irrigation is progressively expanding in several countries of the arid and semi-arid lands. By regulating these N fertilization methods, it is possible to increase the fertilizer N application efficiency and plant productivity and to decrease potential N reduction. This is it may very important in an arid environment region, where N deficiency by volatilization are great (Asadi et al. 2002Asadi, M. E., Clemente, R. S., Gupta, A. D., Loof, R. and Hansen, G. K. (2002). Impacts of fertigations via sprinkler irrigation on nitrate leaching and corn yield in an acid-sulphate soil in Thailand. Agriculture Water Management, 52, 197-213. http://dx.doi.org/10.1016/S0378-3774(01)00136-6.
http://dx.doi.org/10.1016/S0378-3774(01)... ).

The genus Zinnia L. (Asteraceae: Heliantheae) comprises approximately 11 species of annual or perennial herbs or low shrubs. Zinnia violacea Cav. (including Z. elegans Jacq.) is the most widely cultivated species and is prized among garden ornamental for its large, showy inflorescences and diversity of ray floret colors and petal forms. Zinnia is a popular garden flower because it is extensively used in borders, beds and edges; besides, it is grown as a specialty cut flower and is also a good source of foreign exchange if grown extensively. Zinnia is a summer-season flower in Egypt. Plants are erect, 9 – 100 cm in height, sparsely-branched, with large, ovate to lanceolate leaves. Cultivated forms have one to several whorls of ray florets (Reilly 1978Reilly, A. (1978). Park's success with seeds. Green Wood: George W. Park Seed Company.). Good quality and regular supply of flowers can be achieved if proper combinations of N fertilizer with irrigation water are applied to zinnia crop since liquid formulations of various forms of N fertilizers are of current introduction; consequently, studies on fertigation are very limited. There is a need for further studies to decide about the feasibility of using fertigation on a large scale by various farm lands in semi-arid sustems in Egypt. Therefore, the present investigation aimed to examine the effect of drip fertigation in integration with nitrogen fertilizers on the productivity of zinnia plants.

MATERIALS AND METHODS

Field experiments were conducted at the Agricultural Research Station of the Agricultural Research Center, El-Nubaria region, Egypt (longitude: 32°23’ E, latitude: 30°58’ N; 3 m above sea level) through the 2010 – 2011 growing seasons, where the climate is semi-arid with rare rainfall (20 mm per year). Firstly, soil specimens were possessed by an auger from the soil layers 0 – 30, 30 – 60 and 60 – 90 cm (Table 1) to measure chemical and physical characterizations of the experimental field. The soil texture at this site is mostly sandy through its profile (73.1% coarse sand, 19.6% fine sand, 5.0% silt and 2.3% clay). Soil bulk intensity was measured by cylinders 100 mm in diameter and 60 mm in height in accordance with the classical technique (Grossmann and Reinsch 2002Grossmann, R. B. and Reinsch, T. G. (2002). Bulk density and linear extensibility. In A. L. Page, R. H. Miller, and D. R. Keeney (Eds.), Methods of soil analysis. Part IV. Physical Methods (vol. 5, p. 201-228). Madison: ASA; SSSA.). The water content at the wilting point and field capacity were determined in vitro using a pressure plate method (Cassel and Nielsen 1986Cassel, D. K. and Nielsen, D. R. (1986). Field capacity and available water capacity. In A. Klute (Ed.), Methods of soil analysis. Agronomy Monograph No 9 (p. 901-926). Madison: Soil Sciences Society-America.) at 0.03 and 1.5 MPa, respectively. Three replicates with a randomized complete block split plot design were used in each season. The two used irrigation systems; namely, surface and subsurface drip irrigation, represented the main plot. The 4 nitrogen fertilization rates (0, 30, 60 and 120 kg N∙ha^–1) as urea (46.6% of N), referred as N0, N30, N60 and N120, respectively, were randomly nested within each main plot of the irrigation system. Nitrogen fertilizer was added in 6 weekly doses starting 30 days after sowing because the application of N in split doses not only enhances absorption by the plants and reduces leaching and volatilization losses of N, but also becomes available to the plants during initiation of flowers (Iftikhar et al. 2007Iftikhar, A., Tanveer, A., Shahzad, Z. and Azhar N. (2007). Response of an elite cultivar of zinnia (zinnia elegans cv. giant dahlia flowered) to varying levels of nitrogenous fertilizer. Sarhad Journal of Agriculture, 23, 309-312.). Phosphorus fertilizer was applied at a level of 13.5 kg∙ha^–1 of P as calcium superphosphate. All phosphorus was added basally prior planting in all treatments, while the potassium fertilizer was applied after 5 weeks from planting at a value of 41.5 kg∙ha^–1 of K as potassium sulphate by fertigation in 2 equal biweekly amounts. Pests, diseases and weeds control was done at the appropriate time. Hand-harvest was performed about 120 days after sowing. Seeds of zinnia (Zinnia elegans Jacq. cv. “Giant Dahlia Flowered Blue Point Series”) were sown in plastic pots of 40 cm diameter. Seedlings were transplanted at 2 leaf stages in 3 × 0.9 m plots. Plants row spacing was 45 cm, and the distance between each plant was 30 cm; each row had its own irrigation line positioned near the plants. Plots were separated by border plots. Two seedlings were sown around each dripper to obtain a final plant population of 24 plants plot^–1.

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Table 1
Physical and chemical properties of the experimental field soil (averaged over two seasons).

Two common irrigation systems were used to irrigate zinnia plants. The first was surface drip irrigation (SDI) and the second was subsurface drip irrigation (SSDI). The drip irrigation lines were twin-wall drip tapes (GR is the common commercial name), with outlets spaced at every 0.5 m, and the drippers used were of a standard (4 L∙h^–1) discharge at 1.5 bar working pressure. Drip irrigation lines lay above and under rims of plant rows, the composition depth of the subsurface drip lines was 0.25 m with 0.5 m between lateral rows, and the source of irrigation water was groundwater. The specimens of water were collected each irrigation time to analyze the electrical conductivity (EC), main anions (HCO^3–, Cl^–, and CO₃^2–), and main cations (Mg²⁺, Ca²⁺, K⁺, and Na⁺) and (Chapman and Pratt, 1982Chapman, H. D. and Pratt, P. F. (1982). Methods of analysis for soil, plants and waters. Riverside: University of California.), while SO₄^2-ions were calculated as the variance between total cations and anions. Means of value of irrigation water analysis are shown in Table 2.

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Table 2
Some chemical analyses of the irrigation water. Each value into the table express the mean of irrigation samples (six replicates/value).

The applied irrigation water amount (I) was calculated based on the calculated water requirements for zinnia (mm) using the reference daily evapotranspiraiton (ETo; mm.day^-1) and the crop coefficient (Kc), based on the following equation:

According to Allen et al. (1998)Allen, R. G., Raes, L. S. and Smith, D. M. (1998). Crop evapotranpiration - guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56., the Penman-Monteith method was used to calculate ETo. In this regard, daily meteorological data from a station located away about 500 m from the study site were used. The Food and Agriculture Organization (FAO) Penman-Monteith equation, given by Allen et al. (1998)Allen, R. G., Raes, L. S. and Smith, D. M. (1998). Crop evapotranpiration - guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56., is:

where:

R_n is the net radiation at the crop surface (MJ∙m^–2∙day^–1), G is the soil heat flux density (MJ∙m^–2∙day^–1), T is the mean daily air temperature at 2 m height (°C), U₂ means the wind speed at 2 m height (m∙s^–1), e_s is the saturation vapor pressure (kPa), e_arefers to the actual vapor pressure (kPa), e_s – e_a is the saturation vapor pressure deficit (kPa), ∆ is the slope of the saturation vapor pressure curve (kPa∙°C^–1), and γ is the psychrometric constant (kPa∙°C^–1).

The Kc is defined as the ratio between the crop evapotranspiration rate and the reference evapotranspiration rate. Since localized Kcvalues were not available for the study area, the values of Kcsuggested by FAO-56 (Allen et al. 1998Allen, R. G., Raes, L. S. and Smith, D. M. (1998). Crop evapotranpiration - guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56.) were used. The Kc values of zinnia used (0.36, 1.07, and 1.38, at the initial-, mid-, and late-season stages, respectively) represent the recommended values for a sub-humid climate (minimum relative humidity, RHmin≈ 45%) with a moderate wind speed (U2 ≈ 2 m∙s^–1). These recommended values must be adjusted in other areas, where the RHmin differs from 45% and the wind speed is, sometimes, greater than 2 m∙s^–1 or, occasionally, less than 2 m∙s^–1. The Kc value (larger than 0.45) for the mid-season stage was adjusted using the following equation:

table 2. Some chemical analyses of the irrigation water. Each value into the table express the mean of irrigation samples (six replicates/value).

where:

Kc (table) is the Kc recommended by FAO-56 (Allen et al. 1998Allen, R. G., Raes, L. S. and Smith, D. M. (1998). Crop evapotranpiration - guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56.) and h is the mean zinnia height during the mid-season stage (m).

After adjustment, the rates of Kc values for the 2010 – 2011 growing seasons in the primary, middle and end of season stages were 0.36, 1.07, and 1.38, respectively. The drip irrigation efficacy was assumed to be 0.9, and the root extension coefficient was taken to be 0.8 (Moon and Gulik 1996Moon, D. and Gulik, W. V. (1996). Irrigation scheduling using GIS. Proceedings of the International Conference on Evapotranspiration and Irrigation Scheduling; San Antonio, USA.).

A random specimen of three plants from each plot was taken for recording growth characteristics, viz., plant height per plant, biomass as well as total dry matter (TDM) of shoots, roots and flowers per plant, number of branches and flowers as well as flower diameter per plant. To determine the concentration of nutrients in the leaves and roots, plant tissue analysis was carried out after the leaves and root had been dried in an oven at 70 °C for 48 h and grounded. For the tissues analysis, a 0.25-g sample was digested using wet ash method. The semimicro-Kjeldahl method was used to estimate the total nitrogen content in plants (Bremner and Mulvaney 1982Bremner, J. M. and Mulvaney, C. S. (1982). Total nitrogen. In A. L. Page, R. H. Miller and D. R. Keeney (Eds.), Methods of soil analysis. Part II. Chemical and Microbiological Properties: Agronomy (vol. 9, 2nd ed., p. 595-641). Madison: ASA; SSSA.).

Total P was measured colorimetrically using spectrophotometer (Spekol) at 680 nm (Cottenie et al. 1982Cottenie, A., Verloo, M., Kiekens, L., Velghe, G. and Camerlynck, R. (1982). Chemical analysis of plant and soil; [accessed 2015 Oct. 21]. http://www.fao.org/docrep/018/ar117e/ar117e.pdf
http://www.fao.org/docrep/018/ar117e/ar1... ), whereas total potassium was determined by using Gallen Kamp flame photometer (Cottenie et al. 1982Cottenie, A., Verloo, M., Kiekens, L., Velghe, G. and Camerlynck, R. (1982). Chemical analysis of plant and soil; [accessed 2015 Oct. 21]. http://www.fao.org/docrep/018/ar117e/ar117e.pdf
http://www.fao.org/docrep/018/ar117e/ar1... ). Also, total micronutrients (Fe-Mn-Zn) concentration was determined in the digestive solution of HClO₄, HNO₃ and H₂SO₄, according to Chapman and Pratt (1982)Chapman, H. D. and Pratt, P. F. (1982). Methods of analysis for soil, plants and waters. Riverside: University of California., using atomic absorption spectrophotometer (PerkinElmer model 5000). SImilarly, plant samples have been collected baed on the growth stage and stored for analyzing the nutrient uptake pattern. N, P, K, Fe, Mn, and Zn contents in all parts of the plant were analyzed as percentage on dry weight basis and computed to kg∙ha^–1. Similar procedures were approved in the second-season crop also. Reducing sugar, as well as non-reducing sugar percentage, and flower anthocyanins contents (mg∙g^–1) were estimated on a spectrophotometer by using a standard curve (Association of Analytical Communities 1984Association of Analytical Communities (1984) Official methods of analysis; [accessed 2015 Oct. 21]. http://www.eoma.aoac.org
http://www.eoma.aoac.org... ). However, chlorophyll a and b in the leaves was determined according to Moran (1982)Moran, R. (1982). Formulae for determination of chlorophylls pigment extracted with N-N-dimethyl-formamid. Plant Physiology, 69, 1376-1381..

On the initial stage and the post-harvest stage, plant samples were taken randomly to study the effect of integrated management on soil fertility and to evaluate the effect of soil characterizations on crop performance in the field.

Specimens were taken from the planted soil layer (upper 15 cm), using a single auger and combining 12 samples equally dispersed over the field to 1 composite specimen. The specimens were air-dried, mashed and gritted, and other particles of more than 2 mm were removed with a sieve. For judging completely the characteristics of the soil used, the best methods were applied.

The particle size distribution of the soil was examined following the method described by Dewis and Fertias (1970)Dewis, J. and Fertias, F. (1970). Physical and chemical methods of soil and water analysis. Soils Bulletin No. 10. Rome, FAO; [accessed 2015 Oct. 21]. ttp://www.fao.org/docrep/017/a2060e/a2060e.pdf. Whereas, the Darcy equation was used to measure the hydraulic conductivity according to Singh (1980)Singh, R. A. (1980). Soil physical analysis. New Delhi: Kalyani Publisher.. Collins Calcimeter was used to calculate the total Ca gasometrically as calcium carbonate following the method described by Dewis and Fertias (1970)Dewis, J. and Fertias, F. (1970). Physical and chemical methods of soil and water analysis. Soils Bulletin No. 10. Rome, FAO; [accessed 2015 Oct. 21]. ttp://www.fao.org/docrep/017/a2060e/a2060e.pdf. Soil reaction (pH) was determined in saturated soil paste (Richards 1954Richards, L. A. (1954). Diagnosis and improving of saline and alkaline soils. U.S., Salinity Laboratory Staff. Agriculture Handbook, No 60.) by combined electrode pH meter. Total soluble salts were determined by calculating the electrical conductivity in the extraction of saturated soil paste in dS∙m^–1 (Jackson 1967Jackson, M. L. (1967). Soil chemical analysis. New Delhi: Prentice-Hall of India). The saturated soil paste extract was used to measure the water soluble cations (Na⁺, Ca²⁺, K⁺, and Mg²⁺) and anions (Cl^–, HCO^3–, and CO₃^2–) as according to Hesse (1971)Hesse, P. R. (1971). A text book of soil chemical analysis. London: Chemical Pub. Co.. In the mean time, the difference between total cations and total anions was considered as the sulphate (SO₄^2–) ions concentration. A standardized versenate solution was used to assess the total soluble Mg²⁺ and Ca²⁺ by titration. Titration was, also, used to measure the soluble HCO^3– and CO₃^2– using standardized H2SO4 solution. Whereas, a the same method using a standardized AgNO₃ solution was used to determine soluble Cl^–ions. For determination of soluble cations (Na⁺ and K⁺ ions), the flame photometer method was used. Soil available N was determined by applying the same method for the total N in the plant. Soil available phosphorus was carried according to Jackson (1967)Jackson, M. L. (1967). Soil chemical analysis. New Delhi: Prentice-Hall of India. Available potassium was determined following the method described by Hesse (1971)Hesse, P. R. (1971). A text book of soil chemical analysis. London: Chemical Pub. Co.. On the other hand, available iron, zinc and manganese were described by Lindsay and Norvell (1978)Lindsay, W. L. and Norvell, W. A. (1978). Development of a DTPA soil test for zinc, iron, manganese and copper. Soil Science Society of America Journal, 42, 421-428. http://dx.doi.org/10.2136/sssaj1978.03615995004200030009x.
http://dx.doi.org/10.2136/sssaj1978.0361... . The DTPA method (described by Lindsay and Norvell 1978Lindsay, W. L. and Norvell, W. A. (1978). Development of a DTPA soil test for zinc, iron, manganese and copper. Soil Science Society of America Journal, 42, 421-428. http://dx.doi.org/10.2136/sssaj1978.03615995004200030009x.
http://dx.doi.org/10.2136/sssaj1978.0361... ) was used to extract the available Fe²⁺, Zn²⁺ and Mn²⁺ and then measured using atomic absorption spectrophotometer (PerkinElmer model 5000).

Statistical analyses were carried out using two-factor analysis of variance (ANOVA). Means were separated by Duncan’s multiple-range tests by the least significant difference (LSD; p ≤ 0.05) method using the Costat software (Cohort, Berkeley, CA, USA). All measurements were performed four times for each treatment, and the means were recorded as standard errors (SE).

RESULTS AND DISCUSSION

Data presented in Table 3 show that drip irrigation system (SDI and SSDI) increased growth and yield, and this effect was extremely significant (p < 0.05). It is clear that subsurface drip irrigation was related with higher growth and flower quality than surface drip irrigation. Averaged over the two seasons, the subsurface drip irrigation resulted in an increase in plant height, branches number, shoot dry weight, root dry weight, flower diameter, flower number and flowers dry weight by 4.84, 26.43, 16.70, 2.68, 16.48, and 7.15%, respectively, when compared with the surface drip irrigation (Table 3). The capability of subsurface drip irrigation to improve growth and yield could be attributed to the less water lost from soil surface out of vaporization that led to ideal crop yield. Furthermore, subsurface drip irrigation improved the efficiency of water and fertilizers use; this may be attributed to its ability to allow the maintenance of optimum soil moisture content in the root zone (Thompson and Doerge 1996Thompson, T. L. and Doerge, T. A. (1996). Nitrogen and water interactions in subsurface trickle irrigated leaf lettuce. II. Agronomic, economic, and environmental outcomes. Soil Science Society of America Journal, 60, 168-173. http://dx.doi.org/10.2136/sssaj1996.03615995006000010027x.
http://dx.doi.org/10.2136/sssaj1996.0361... ).

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Table 3
Effect of drip irrigation system, different nitrogen fertilizer rates and their interactive effect on growth parameters (vegetative and flowering) of zinnia plant (mean data for two years).

Regarding the effect of N fertilizer, it is obvious that N fertilizer additive through fertigation system improved growth and flowering quality, and this effect was greatly significant (p < 0.05). At the same time, N fertilizer rate at 120 kg∙ha^–1 produced higher yield than the application rate of 30 or 60 kg∙ha^–1. This is due to the high concentration of nitrogen, which leads to an increase in the number of cells and the cell size of the leaf with an overall increase in leaf production as reported by Hopkins and Hüner (1973)Hopkins, W. G. and Hüner, N. P. A. (1973). Introduction to Plant Physiology. Hoboken: Wiley & Sons.. This may be explained by the fact that Nitrogen is an necessary component of amino acids, which are the building blocks of proteins and nucleic acids, which prepare genetic material and protein (Haque and Jakhro 2001Haque, I. and Jakhro, A. A. (2001). Soil and fertilizer potassium. In A. Rashid, Soil Science (p. 261-263). Islamabad: National Book Foundation.), which are useful in plant growth and also encourage a fast growth. Moreover, Fortun et al. (2006)Fortun, A., Benayas, J. and Fortun, C. (2006). The effects of fulvic and nitrogen fertilizers on soil aggregation, a micromorphological study. European Journal of Soil Sciences, 41, 563-572. stated that the improving flowering growth may be attributed to the increase in soil gatherings due to application of nitrogen fertilizer. The composition of these aggregates could protect zinnia plants to be enclosed under soil at all growth stages, and this could improve flower quality. In contrast, our results suggest that fertigation with a urea-based fertilizer seems to be the most suitable option in order to improve flower quality and sustain productivity under specific conditions of these drip irrigation systems, especially, when subsurface drip irrigation system was applied.

The effect of interaction between nitrogen fertilizer application rates and irrigation treatments was significant on the increase in the growth of zinnia plant and flowering quality indicators (Table 2).

Meanwhile, the treatment of application with nitrogen fertilizer at 120 kg∙ha^–1 with subsurface drip irrigation system recorded higher plant height (58.42 cm) and number of branches (8.91), number of flowers (15.67), as well as flower per plant, root dry weight and shoot dry weight (7.92, 24.54, and 111.37 g, respectively). The increase in yield properties in drip fertigation is probably related to improved uptake and availability of nutrients resulting in promoted photosynthesis, leaves extension and translocation of nutrients to reproductive organs compared with conventional nutrients application to soil. These results are in agreement with those obtained by Elhindi et al. (2006)Elhindi, K. M., El-Shika, D. M. and El-Ghamry, A. M. (2006). Response of cineraria plant to water stress and nitrogen fertilizer sources under drip irrigation system. Journal of Agriculture Sciences, 31, 3129-3146., Gengoglan et al. (2006)Gengoglan, C., Altunbey, H. and Gengoglan, S. (2006). Response of green bean (phaseolus vulgaris L.) to subsurface drip irrigation and partial rootzone-drying irrigation. Agriculture Water Management, 84, 274-280., El-Shawadfy (2008)El-Shawadfy, M. (2008). Influence of different irrigation systems and treatments on productivity and fruit quality of some bean varieties (Master's thesis). Cairo: Ain Shams University., and Navid et al. (2009)Navid, R., Jahanfar, D. and Hossein, A. F. (2009). Effects of nitrogen fertilizer and irrigation regimes on seed yield of calendula (Calendula officinalis L.). Journal of Agricultural Biotechnology and Sustainable Development, 1, 24-28..

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Table 4
Effect of drip irrigation system, different nitrogen fertilizer rates and their interaction on chemical composition (mean data for two years).

Relevant data in Table 4 showed the chemical compositions (chlorophylls, flower anthocyanins content and carbohydrates, viz., reducing and non-reducing sugars percentage) of zinnia plants as affected by irrigation systems. SSDI slightly increased the chemical composition in zinnia plant compared with SDI. It was known that the drip irrigation is significant in increasing the nitrogen availability and other nutrients and in increasing their absorption by the plant, increasing total chlorophylls content in leaves. Those came supporting the fact that , under water deficiency stress, the stomata reacts by turning its state to blocked or a half-blocked. and this induce a reduction in uptake CO₂ and subsequently the plants exhaust a huge amount of energy to absorb water, which negatively impact the photosynthetic activities, and then reduce the productivity of plants. These findings indicated that drip irrigation may increase the availability of water in root area, leading to improvements in plant water status and better stomatal conductance (Nunez-Barrious 1991Nunez-Barrious, A. (1991). Effect of soil water deficits on the growth and development of dry beans ( Phaseolus vulgaris L.) at different stages of growth (PhD thesis). East Lansing: Michigan State University.), which eventually reflects on photoassimilate production (Nielsen and Nelson 1998Nielsen, D. C. and Nelson, N. O. (1998). Black bean sensitivity to water stress at various growth stages. Crop Sciences, 38, 422-427.).

Results in Table 4 reveal that the maximum values of chemical compositions were obtained with the highest fertilizer application rate (120 kg∙ha^–1), whereas, the minimum values were obtained by fertigation with the lowest levels of N or without fertilizer application. In this regard, the stimulating effect of nitrogen fertilizer on the increase in the photosynthetic pigments might be due to the promoting effect of the appropriate fertigation, indirectly or directly, on the increase in the absorption and availability of the essential minerals, particularly NH₄⁺, Mg²⁺, and Fe²⁺ cations, which are necessary for the activation of enzyme and formation of chlorophyll and chloroplasts (Stofella and Kahn 2001Stofella, P. J. and Kahn, B. A. (2001). Compost utilization in horticultural cropping system. Boca Raton: CRC Press.). Furthermore, Cooper (1974)Cooper, J. E. (1974). Effects of post-planting applications of nitrogenous fertilizers on grain yield, grain protein content, and mottling of wheat. Queensland Journal of Agricultural and Animal Sciences, 31, 33-42. reported that the N fertilizers commonly cause insufficiency of potassium, enhanced carbohydrate storage and decreased proteins, adjustment in amino acid balance and, then, change in the aspect of proteins; these are a main nutrient in chlorophyll production. Leaf chlorophyll contents were higher with a high dose of nitrogen application (Rathore et al. 1985Rathore, S. V. S., Dera, D. K. and Chand, U. (1985). Studies of nitrogen nutrition through foliar spray of urea on the performance of African marigold. Udyarika, 5, 37-40.).Present experiments strongly supports that the nitrogen application indirectly increase the amount of carbohydrates, as a result of enhancing the plants metabolites synthesis which positively affects the productive metabolic activities, and hence raised the carbohydrates content. Higher N application dose showed to be more effective to increase flower quality and yield as well as to reduce the crop duration through early flowering. These treatments encouraged zinnia plants to produce increased photosynthates, which, in sequence, produce higher growth rate, flower good quality, and then early production (Chadaha et al. 1999Chadaha, A. S. S., Rathore, S. V. S. and Genesh, R. K. (1999). Influence of N and P fertilization and ascorbic acid on growth and flowering of African marigold. South Indian Horticulture, 47, 342-346.).

The effect of the interaction between nitrogen fertigation rate and drip irrigation was significant (p < 0.05) (Table 4). However, it is clear that the application of N fertilization rate at 120 kg∙ha^–1 with subsurface drip irrigation system was the superior treatment. Similar results to those described were found by Anuradha et al. (1990)Anuradha, K. K., Pampapathy, N. and Naryan R. (1990). Effect of nitrogen and phosphorus on flowering, yield and quality of Marigold. Indian Journal of Horticulture, 47, 353-357., Belorkar et al. (1992)Belorkar, P. V., Patil, B. N., Golliwar, V. J. and Kothare, A. J. (1992). Effect of nitrogen levels and spacing on growth, flowering and yield of African marigold (Tagetes erecta L.). Journal of Crop Sciences, 2, 62-64., and Chadaha et al. (1999)Chadaha, A. S. S., Rathore, S. V. S. and Genesh, R. K. (1999). Influence of N and P fertilization and ascorbic acid on growth and flowering of African marigold. South Indian Horticulture, 47, 342-346..

Regarding the effect of irrigation system, Table 5 shows that irrigation system slightly increased element concentrations in zinnia plants, but it was significantly higher with the subsurface drip irrigation compared to the surface drip. It appears that subsurface drip irrigation creates more appropriate conditions in the root zone area for zinnia plant growth and productions. These results are in agreement with those obtained by Lamm and Trooien (2003)Lamm, F. R. and Trooien, T. P. (2003). Subsurface drip irrigation for corn productivity, a review of 10 years of research in Kansas. Irrigation Sciences, 22, 195-200. http://dx.doi.org/10.1007/s00271-003-0085-3.
http://dx.doi.org/10.1007/s00271-003-008... , as well as Dukes and Scholberg (2005)Dukes, M. D. and Scholberg, J. M. (2005). Soil moisture controlled subsurface drip irrigation on sandy soils. American Society of Agricultural Engineers, 21, 89-101..

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Table 5
Effect of drip irrigation system, different nitrogen fertilizer rates and their interaction on element concentrations in zinnia plants at harvest (mean data for two years).

Data revealed that application of N rates had an extremely significant effect on the increase in both micro and macronutrients remained in plants (Table 5). The application rate of 120 kg∙ha^–1 established the highest concentration of nutrients and uptake in plants compared with 30, 60 kg∙ha^–1and the control treatment. This is because the higher concentration of N, P, and K elements in the leaves of zinnia plants, which is due to the increasing soil moisture content that caused a marked effect on the increase in the solubility of such elements in the soil, promoting the absorbing efficiency of such elements by the plants; it can also form aqueous complexes with micronutrients (Aiken et al. 1985Aiken, G. R., Mcknight, D. M., Wershaw, R. L. and Maccarthy, P. (1985). Nitrogen fertilizers in soil, sediment and water. New York: Wiley-Interscience). Moreover, the increase of N fertilizer application rates was linked to the reduction of nutrients leaching that was reflected on the increase in micro and macronutrients concentration in zinnia plants. This indicated a positive effect of the zinnia response to N fertilizer (120 kg∙ha^–1) application by promoting zinnia biomass because of higher N uptake by its roots (Table 5) that showed higher N concentration in the plants. This indicated higher N concentration in the plants. Gaffarzadeh et al. (1998)Gaffarzadeh, M., Prechac, F. G. and Cruse, R. M. (1998). Fertilizer and soil nitrogen use by corn and border crops in a strip intercropping system. Agronomy Journal, 90, 758-762. http://dx.doi.org/10.2134/agronj1998.00021962009000060007x.
http://dx.doi.org/10.2134/agronj1998.000... pointed out that nutrient uptake, particularly nitrogen, increased plant production.

About the effect of combination of nitrogen fertilizer levels and drip irrigation systems, Table 5 revealed that this effect was significant. Nitrogen fertilizer application at 120 kg∙ha^–1 with subsurface drip irrigation system gave the highest values of micro and macronutrients remained in zinnia shoots. The nitrogen uptake was considerably higher under drip fertigation at 120 kg∙ha^–1 compared with the other treatments. The P and K uptake values were less or more similar to N uptake. On the other hand, the soil solution phase, which determined mostly by the available soil water, greatly affects the availability and concentration of many nutrients in the soil. The continuous supply of water under drip fertigiation system increases the available water in the soil, and results in more available nutrients and the soil, that in turn increases the plant’s nutrient uptake. Moreover, the total biomass production in plants was increased as a result of the increase of nutrient uptake resulted from the higher availability of nutrients and water in the soil. This increase in uptake of nutrients may also be referred to the split application of N and K nutrients using the drip fertigation system which minimize the loss in nutrients and make them available to the crop continuously. Tumbare et al. (1999)Tumbare, A. D., Shinde, B. N. and Bhoite, S. U. (1999). Effects of liquid fertilizer through drip irrigation on growth and yield of okra ( Hibiscus esculentus). Indian Journal of Agronomy, 44, 176-178. referred the increase in nutrient uptake to the split application of nutrients using drip fertigation that minimizes the loss in nutrients by leaching and make them available to the plant. The increased yield under fertigation system could be attributed to the increased nutrient uptake, effiiciency of fertilizer using and percentage of nutrient uptake compared to the amount used (Mohammad 2004Mohammad, M. J. (2004). Utilization of applied fertilizer nitrogen and irrigation water by drip-fertigated squash as determined by nuclear and traditional techniques. Nutrient Cycling in Agroecosystems, 68, 1-11. http://dx.doi.org/10.1023/B:FRES.0000012229.61906.6c.
http://dx.doi.org/10.1023/B:FRES.0000012... ). In addition, Bharambe et al. (1997)Bharambe, P. R., Narwade, S. K., Oza, S. R., Vaishnava, V. A., Shelke, D. K. and Jadhav, G. S. (1997). Nitrogen management in cotton through drip irrigation. Journal of the Indian Society of Soil Science, 45, 705-709. and Veeraputhiran (2000)Veeraputhiran, R. (2000). Drip fertigation studies in hybrid cotton (PhD thesis). Coimbatore: Tamil Nadu Agricultural University. have reported similar findings regarding the increased uptake of nutrients under drip fertigation systems.

In general, an increase in soil available micro and macronutrients at post-harvest was noticed as compared with initial soil nutrient status. Regarding the effect of drip irrigation systems, subsurface drip irrigation increased soil fertility after zinnia plants harvest compared to soil fertility under surface drip irrigation system.

Data in Table 6 showed that the application of N fertilizer with fertigation program had a highly significant effect on the increase in micro and macronutrients remained in soil after zinnia plants harvest. This is mainly attributed to the increase in nitrogen fertilizer rates associated with the decrease of nutrients leaching, which reflected an increasing macronutrients concentration, such as nitrogen in plants, and increasing concentration of these nutrients in soil after plants harvest (Elhindi et al. 2006Elhindi, K. M., El-Shika, D. M. and El-Ghamry, A. M. (2006). Response of cineraria plant to water stress and nitrogen fertilizer sources under drip irrigation system. Journal of Agriculture Sciences, 31, 3129-3146.).

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Table 6
Effect of drip irrigation system, different nitrogen fertilizer rates and their interaction on post-harvest soil available nutrient status (mean data for two years).

The was a significant (p < 0.05) interaction effect between drip irrigation systems and N fertilizer rates (Table 6). The treatments showed significant influence on post-harvest soil available nutrient status, and the highest micro and macronutrients values were noticed under drip fertigation with 120 kg∙ha^–1. Surface irrigation with soil application of 30 kg∙ha^–1 recorded the lowest values of post-harvest soil available nutrients. The availability and distribution of nutrients in the soil depend on their solubility, moisture and difference. The higher available N, P, K, Fe, Mn, and Zn in the soil after plant harvesting when using drip fertigation system could be attributed to the minimal losses in minerals via leaching and the enhancement of nutrients movement in the soil comparing to surface and/ or subsurface drip irrigation system. Slight improvement in the post-harvest soil fertility levels of N, P, K, Fe, Mn, and Zn was noticed in fertigation plots. This confirmed that fertilizers solubilize the unavailable phosphorus to available P form and increase the P use efficiency. Inclusion of fertilizers in the nutrient management program has found to increase the yield of crops by 5 – 10% and the nutrient use efficiency.Supply of water and N fertilizers at shorter intervals increased the nutrients availability in the soil. Moreover, Malik et al. (1994)Malik, R. S., Kumar, K. A. and Bhandar, I. (1994). Influence of nitrogen application by drip irrigation on nutrients availability in soil and uptake by pea. Journal of the Indian Society of Soil Science, 44, 508-509. and Bharambe et al. (1997)Bharambe, P. R., Narwade, S. K., Oza, S. R., Vaishnava, V. A., Shelke, D. K. and Jadhav, G. S. (1997). Nitrogen management in cotton through drip irrigation. Journal of the Indian Society of Soil Science, 45, 705-709. have reported that there was increase in the availability of soil nutrients under drip fertigation systems compared to the direct application to the soil.

CONCLUSION

In conclusion, present study indicated that the growth and flowering parameters of zinnia plants was highly enhanced by the application subsurface drip irrigation than it was under surface drip irrigation system. Higher nitrogen application levels not only increased growth rate and production of best-quality flower of zinnia but more enhanced leaf nutrient rates and flower anthocyanin composition. Under semi-arid conditions, drip fertigation with N fertilizers will aid in easy application and concentration of nutrients suitable to the plant according to its developmental stage. It reduced salinization and fluctuation in nutrient values in soil during the plant growing season, promoted higher fertilizer use effectiveness and improved plant productivity.

ACKNOWLEDGEMENTS

The authors sincerely appreciate the support provided by the Deanship of Scientific Research, King Saud University, Saudi Arabia for its funding to this research through the Research Group No. RG-1436-020.

REFERENCES

Abalos, D., Sanchez-Martin, L., Garcia-Torres, L., van Groenigen, J. W. and Vallejo, A. (2014). Management of irrigation frequency and nitrogen fertilization to mitigate GHG and NO emissions from drip-fertigated. Crop Sciences Environmental, 490, 880-888. http://dx.doi.org/10.1016/j.scitotenv.2014.05.065
» http://dx.doi.org/10.1016/j.scitotenv.2014.05.065
Aiken, G. R., Mcknight, D. M., Wershaw, R. L. and Maccarthy, P. (1985). Nitrogen fertilizers in soil, sediment and water. New York: Wiley-Interscience
Allen, R. G., Raes, L. S. and Smith, D. M. (1998). Crop evapotranpiration - guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56.
Anuradha, K. K., Pampapathy, N. and Naryan R. (1990). Effect of nitrogen and phosphorus on flowering, yield and quality of Marigold. Indian Journal of Horticulture, 47, 353-357.
Asadi, M. E., Clemente, R. S., Gupta, A. D., Loof, R. and Hansen, G. K. (2002). Impacts of fertigations via sprinkler irrigation on nitrate leaching and corn yield in an acid-sulphate soil in Thailand. Agriculture Water Management, 52, 197-213. http://dx.doi.org/10.1016/S0378-3774(01)00136-6.
» http://dx.doi.org/10.1016/S0378-3774(01)00136-6
Association of Analytical Communities (1984) Official methods of analysis; [accessed 2015 Oct. 21]. http://www.eoma.aoac.org
» http://www.eoma.aoac.org
Belorkar, P. V., Patil, B. N., Golliwar, V. J. and Kothare, A. J. (1992). Effect of nitrogen levels and spacing on growth, flowering and yield of African marigold (Tagetes erecta L.). Journal of Crop Sciences, 2, 62-64.
Bharambe, P. R., Narwade, S. K., Oza, S. R., Vaishnava, V. A., Shelke, D. K. and Jadhav, G. S. (1997). Nitrogen management in cotton through drip irrigation. Journal of the Indian Society of Soil Science, 45, 705-709.
Bremner, J. M. and Mulvaney, C. S. (1982). Total nitrogen. In A. L. Page, R. H. Miller and D. R. Keeney (Eds.), Methods of soil analysis. Part II. Chemical and Microbiological Properties: Agronomy (vol. 9, 2^nd ed., p. 595-641). Madison: ASA; SSSA.
Burt, C. O., Connor, K. and Ruehr, T. (1998). Chemicals for fertigation; [accessed 2015 Oct. 21]. http://www.itrc.org/papers/pdf/chemicalsforfertigation.pdf
» http://www.itrc.org/papers/pdf/chemicalsforfertigation.pdf
Cassel, D. K. and Nielsen, D. R. (1986). Field capacity and available water capacity. In A. Klute (Ed.), Methods of soil analysis. Agronomy Monograph N^o 9 (p. 901-926). Madison: Soil Sciences Society-America.
Chadaha, A. S. S., Rathore, S. V. S. and Genesh, R. K. (1999). Influence of N and P fertilization and ascorbic acid on growth and flowering of African marigold. South Indian Horticulture, 47, 342-346.
Chapman, H. D. and Pratt, P. F. (1982). Methods of analysis for soil, plants and waters. Riverside: University of California.
Cooper, J. E. (1974). Effects of post-planting applications of nitrogenous fertilizers on grain yield, grain protein content, and mottling of wheat. Queensland Journal of Agricultural and Animal Sciences, 31, 33-42.
Cottenie, A., Verloo, M., Kiekens, L., Velghe, G. and Camerlynck, R. (1982). Chemical analysis of plant and soil; [accessed 2015 Oct. 21]. http://www.fao.org/docrep/018/ar117e/ar117e.pdf
» http://www.fao.org/docrep/018/ar117e/ar117e.pdf
Darwish, T. M., Atallah, T. W., Hajhasan, S. and Haidar, A. (2006). Nitrogen and water use efficiency of fertigated processing potato. Agriculture Water Management, 85, 95-104. http://dx.doi.org/10.1016/j.agwat.2006.03.012.
» http://dx.doi.org/10.1016/j.agwat.2006.03.012
Dewis, J. and Fertias, F. (1970). Physical and chemical methods of soil and water analysis. Soils Bulletin No. 10. Rome, FAO; [accessed 2015 Oct. 21]. ttp://www.fao.org/docrep/017/a2060e/a2060e.pdf
Dukes, M. D. and Scholberg, J. M. (2005). Soil moisture controlled subsurface drip irrigation on sandy soils. American Society of Agricultural Engineers, 21, 89-101.
El-Shawadfy, M. (2008). Influence of different irrigation systems and treatments on productivity and fruit quality of some bean varieties (Master's thesis). Cairo: Ain Shams University.
Elhindi, K. M., El-Shika, D. M. and El-Ghamry, A. M. (2006). Response of cineraria plant to water stress and nitrogen fertilizer sources under drip irrigation system. Journal of Agriculture Sciences, 31, 3129-3146.
Fortun, A., Benayas, J. and Fortun, C. (2006). The effects of fulvic and nitrogen fertilizers on soil aggregation, a micromorphological study. European Journal of Soil Sciences, 41, 563-572.
Gaffarzadeh, M., Prechac, F. G. and Cruse, R. M. (1998). Fertilizer and soil nitrogen use by corn and border crops in a strip intercropping system. Agronomy Journal, 90, 758-762. http://dx.doi.org/10.2134/agronj1998.00021962009000060007x.
» http://dx.doi.org/10.2134/agronj1998.00021962009000060007x
Gengoglan, C., Altunbey, H. and Gengoglan, S. (2006). Response of green bean (phaseolus vulgaris L.) to subsurface drip irrigation and partial rootzone-drying irrigation. Agriculture Water Management, 84, 274-280.
Grossmann, R. B. and Reinsch, T. G. (2002). Bulk density and linear extensibility. In A. L. Page, R. H. Miller, and D. R. Keeney (Eds.), Methods of soil analysis. Part IV. Physical Methods (vol. 5, p. 201-228). Madison: ASA; SSSA.
Haque, I. and Jakhro, A. A. (2001). Soil and fertilizer potassium. In A. Rashid, Soil Science (p. 261-263). Islamabad: National Book Foundation.
Hesse, P. R. (1971). A text book of soil chemical analysis. London: Chemical Pub. Co.
Hopkins, W. G. and Hüner, N. P. A. (1973). Introduction to Plant Physiology. Hoboken: Wiley & Sons.
Iftikhar, A., Tanveer, A., Shahzad, Z. and Azhar N. (2007). Response of an elite cultivar of zinnia (zinnia elegans cv. giant dahlia flowered) to varying levels of nitrogenous fertilizer. Sarhad Journal of Agriculture, 23, 309-312.
Jackson, M. L. (1967). Soil chemical analysis. New Delhi: Prentice-Hall of India
Jiusheng, L., Jianjun, Z. and Ren, L. (2003). Water and nitrogen distribution as affected by fertigation of ammonium nitrate from a point source. Irrigation Science, 22, 19-30. http://dx.doi.org/10.1007/s00271-003-0064-8.
» http://dx.doi.org/10.1007/s00271-003-0064-8
Lamm, F. R. and Trooien, T. P. (2003). Subsurface drip irrigation for corn productivity, a review of 10 years of research in Kansas. Irrigation Sciences, 22, 195-200. http://dx.doi.org/10.1007/s00271-003-0085-3.
» http://dx.doi.org/10.1007/s00271-003-0085-3
Lesschen, J. P., Velthof, G. L., Vries, D. E. W., and Kros, J. (2011). Differentiation of nitrous oxide emission factors for agricultural soils. Environmental. Pollution, 159, 3215-22. http://dx.doi.org/10.1016/j.envpol.2011.04.001.
» http://dx.doi.org/10.1016/j.envpol.2011.04.001
Lindsay, W. L. and Norvell, W. A. (1978). Development of a DTPA soil test for zinc, iron, manganese and copper. Soil Science Society of America Journal, 42, 421-428. http://dx.doi.org/10.2136/sssaj1978.03615995004200030009x.
» http://dx.doi.org/10.2136/sssaj1978.03615995004200030009x
Malik, R. S., Kumar, K. A. and Bhandar, I. (1994). Influence of nitrogen application by drip irrigation on nutrients availability in soil and uptake by pea. Journal of the Indian Society of Soil Science, 44, 508-509.
Mohammad, M. J. (2004). Utilization of applied fertilizer nitrogen and irrigation water by drip-fertigated squash as determined by nuclear and traditional techniques. Nutrient Cycling in Agroecosystems, 68, 1-11. http://dx.doi.org/10.1023/B:FRES.0000012229.61906.6c.
» http://dx.doi.org/10.1023/B:FRES.0000012229.61906.6c
Moon, D. and Gulik, W. V. (1996). Irrigation scheduling using GIS. Proceedings of the International Conference on Evapotranspiration and Irrigation Scheduling; San Antonio, USA.
Moran, R. (1982). Formulae for determination of chlorophylls pigment extracted with N-N-dimethyl-formamid. Plant Physiology, 69, 1376-1381.
Navid, R., Jahanfar, D. and Hossein, A. F. (2009). Effects of nitrogen fertilizer and irrigation regimes on seed yield of calendula (Calendula officinalis L.). Journal of Agricultural Biotechnology and Sustainable Development, 1, 24-28.
Nielsen, D. C. and Nelson, N. O. (1998). Black bean sensitivity to water stress at various growth stages. Crop Sciences, 38, 422-427.
Nunez-Barrious, A. (1991). Effect of soil water deficits on the growth and development of dry beans ( Phaseolus vulgaris L.) at different stages of growth (PhD thesis). East Lansing: Michigan State University.
Papadopoulos, I. (2000). Fertigation: present and future prospects. In J. Ryan (Ed.), Plant nutrient management under pressurized irrigation systems in the Mediterranean Region (p. 232-245). Amman: ICARDA.
Rathore, S. V. S., Dera, D. K. and Chand, U. (1985). Studies of nitrogen nutrition through foliar spray of urea on the performance of African marigold. Udyarika, 5, 37-40.
Reilly, A. (1978). Park's success with seeds. Green Wood: George W. Park Seed Company.
Richards, L. A. (1954). Diagnosis and improving of saline and alkaline soils. U.S., Salinity Laboratory Staff. Agriculture Handbook, N^o 60.
Washington: USDA; [accessed 2015 Oct. 21]. http://www.ars.usda.gov/sp2UserFiles/Place/20360500/hb60_pdf/hb60complete.pdf
» http://www.ars.usda.gov/sp2UserFiles/Place/20360500/hb60_pdf/hb60complete.pdf
Singh, R. A. (1980). Soil physical analysis. New Delhi: Kalyani Publisher.
Stofella, P. J. and Kahn, B. A. (2001). Compost utilization in horticultural cropping system. Boca Raton: CRC Press.
Suganya, S. and Sivasamy, R. (2006). Moisture retention and cation exchange capacity of sandy soil as influenced by soil additives. Journal of Applied Sciences Researche, 2, 949-951.
Thompson, T. L. and Doerge, T. A. (1996). Nitrogen and water interactions in subsurface trickle irrigated leaf lettuce. II. Agronomic, economic, and environmental outcomes. Soil Science Society of America Journal, 60, 168-173. http://dx.doi.org/10.2136/sssaj1996.03615995006000010027x.
» http://dx.doi.org/10.2136/sssaj1996.03615995006000010027x
Thompson, T. L., Doerge, T. A. and Godin, R. E. (2000). Nitrogen and water interactions in subsurface drip irrigated cauliflower. I. Plant response. Soil Science Society of America Journal, 64, 406-11.
Tumbare, A. D., Shinde, B. N. and Bhoite, S. U. (1999). Effects of liquid fertilizer through drip irrigation on growth and yield of okra ( Hibiscus esculentus). Indian Journal of Agronomy, 44, 176-178.
Veeraputhiran, R. (2000). Drip fertigation studies in hybrid cotton (PhD thesis). Coimbatore: Tamil Nadu Agricultural University.

Publication Dates

Publication in this collection
Jan-Mar 2016

History

Received
29 Apr 2015
Accepted
10 Sept 2015

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[1] Abalos, D., Sanchez-Martin, L., Garcia-Torres, L., van Groenigen, J. W. and Vallejo, A. (2014). Management of irrigation frequency and nitrogen fertilization to mitigate GHG and NO emissions from drip-fertigated. Crop Sciences Environmental, 490, 880-888. http://dx.doi.org/10.1016/j.scitotenv.2014.05.065
» http://dx.doi.org/10.1016/j.scitotenv.2014.05.065

[2] Aiken, G. R., Mcknight, D. M., Wershaw, R. L. and Maccarthy, P. (1985). Nitrogen fertilizers in soil, sediment and water. New York: Wiley-Interscience

[3] Allen, R. G., Raes, L. S. and Smith, D. M. (1998). Crop evapotranpiration - guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56.

[4] Anuradha, K. K., Pampapathy, N. and Naryan R. (1990). Effect of nitrogen and phosphorus on flowering, yield and quality of Marigold. Indian Journal of Horticulture, 47, 353-357.

[5] Asadi, M. E., Clemente, R. S., Gupta, A. D., Loof, R. and Hansen, G. K. (2002). Impacts of fertigations via sprinkler irrigation on nitrate leaching and corn yield in an acid-sulphate soil in Thailand. Agriculture Water Management, 52, 197-213. http://dx.doi.org/10.1016/S0378-3774(01)00136-6.
» http://dx.doi.org/10.1016/S0378-3774(01)00136-6

[6] Association of Analytical Communities (1984) Official methods of analysis; [accessed 2015 Oct. 21]. http://www.eoma.aoac.org
» http://www.eoma.aoac.org

[7] Belorkar, P. V., Patil, B. N., Golliwar, V. J. and Kothare, A. J. (1992). Effect of nitrogen levels and spacing on growth, flowering and yield of African marigold (Tagetes erecta L.). Journal of Crop Sciences, 2, 62-64.

[8] Bharambe, P. R., Narwade, S. K., Oza, S. R., Vaishnava, V. A., Shelke, D. K. and Jadhav, G. S. (1997). Nitrogen management in cotton through drip irrigation. Journal of the Indian Society of Soil Science, 45, 705-709.

[9] Bremner, J. M. and Mulvaney, C. S. (1982). Total nitrogen. In A. L. Page, R. H. Miller and D. R. Keeney (Eds.), Methods of soil analysis. Part II. Chemical and Microbiological Properties: Agronomy (vol. 9, 2^nd ed., p. 595-641). Madison: ASA; SSSA.

[10] Burt, C. O., Connor, K. and Ruehr, T. (1998). Chemicals for fertigation; [accessed 2015 Oct. 21]. http://www.itrc.org/papers/pdf/chemicalsforfertigation.pdf
» http://www.itrc.org/papers/pdf/chemicalsforfertigation.pdf

[11] Cassel, D. K. and Nielsen, D. R. (1986). Field capacity and available water capacity. In A. Klute (Ed.), Methods of soil analysis. Agronomy Monograph N^o 9 (p. 901-926). Madison: Soil Sciences Society-America.

[12] Chadaha, A. S. S., Rathore, S. V. S. and Genesh, R. K. (1999). Influence of N and P fertilization and ascorbic acid on growth and flowering of African marigold. South Indian Horticulture, 47, 342-346.

[13] Chapman, H. D. and Pratt, P. F. (1982). Methods of analysis for soil, plants and waters. Riverside: University of California.

[14] Cooper, J. E. (1974). Effects of post-planting applications of nitrogenous fertilizers on grain yield, grain protein content, and mottling of wheat. Queensland Journal of Agricultural and Animal Sciences, 31, 33-42.

[15] Cottenie, A., Verloo, M., Kiekens, L., Velghe, G. and Camerlynck, R. (1982). Chemical analysis of plant and soil; [accessed 2015 Oct. 21]. http://www.fao.org/docrep/018/ar117e/ar117e.pdf
» http://www.fao.org/docrep/018/ar117e/ar117e.pdf

[16] Darwish, T. M., Atallah, T. W., Hajhasan, S. and Haidar, A. (2006). Nitrogen and water use efficiency of fertigated processing potato. Agriculture Water Management, 85, 95-104. http://dx.doi.org/10.1016/j.agwat.2006.03.012.
» http://dx.doi.org/10.1016/j.agwat.2006.03.012

[17] Dewis, J. and Fertias, F. (1970). Physical and chemical methods of soil and water analysis. Soils Bulletin No. 10. Rome, FAO; [accessed 2015 Oct. 21]. ttp://www.fao.org/docrep/017/a2060e/a2060e.pdf

[18] Dukes, M. D. and Scholberg, J. M. (2005). Soil moisture controlled subsurface drip irrigation on sandy soils. American Society of Agricultural Engineers, 21, 89-101.

[19] El-Shawadfy, M. (2008). Influence of different irrigation systems and treatments on productivity and fruit quality of some bean varieties (Master's thesis). Cairo: Ain Shams University.

[20] Elhindi, K. M., El-Shika, D. M. and El-Ghamry, A. M. (2006). Response of cineraria plant to water stress and nitrogen fertilizer sources under drip irrigation system. Journal of Agriculture Sciences, 31, 3129-3146.

[21] Fortun, A., Benayas, J. and Fortun, C. (2006). The effects of fulvic and nitrogen fertilizers on soil aggregation, a micromorphological study. European Journal of Soil Sciences, 41, 563-572.

[22] Gaffarzadeh, M., Prechac, F. G. and Cruse, R. M. (1998). Fertilizer and soil nitrogen use by corn and border crops in a strip intercropping system. Agronomy Journal, 90, 758-762. http://dx.doi.org/10.2134/agronj1998.00021962009000060007x.
» http://dx.doi.org/10.2134/agronj1998.00021962009000060007x

[23] Gengoglan, C., Altunbey, H. and Gengoglan, S. (2006). Response of green bean (phaseolus vulgaris L.) to subsurface drip irrigation and partial rootzone-drying irrigation. Agriculture Water Management, 84, 274-280.

[24] Grossmann, R. B. and Reinsch, T. G. (2002). Bulk density and linear extensibility. In A. L. Page, R. H. Miller, and D. R. Keeney (Eds.), Methods of soil analysis. Part IV. Physical Methods (vol. 5, p. 201-228). Madison: ASA; SSSA.

[25] Haque, I. and Jakhro, A. A. (2001). Soil and fertilizer potassium. In A. Rashid, Soil Science (p. 261-263). Islamabad: National Book Foundation.

[26] Hesse, P. R. (1971). A text book of soil chemical analysis. London: Chemical Pub. Co.

[27] Hopkins, W. G. and Hüner, N. P. A. (1973). Introduction to Plant Physiology. Hoboken: Wiley & Sons.

[28] Iftikhar, A., Tanveer, A., Shahzad, Z. and Azhar N. (2007). Response of an elite cultivar of zinnia (zinnia elegans cv. giant dahlia flowered) to varying levels of nitrogenous fertilizer. Sarhad Journal of Agriculture, 23, 309-312.

[29] Jackson, M. L. (1967). Soil chemical analysis. New Delhi: Prentice-Hall of India

[30] Jiusheng, L., Jianjun, Z. and Ren, L. (2003). Water and nitrogen distribution as affected by fertigation of ammonium nitrate from a point source. Irrigation Science, 22, 19-30. http://dx.doi.org/10.1007/s00271-003-0064-8.
» http://dx.doi.org/10.1007/s00271-003-0064-8

[31] Lamm, F. R. and Trooien, T. P. (2003). Subsurface drip irrigation for corn productivity, a review of 10 years of research in Kansas. Irrigation Sciences, 22, 195-200. http://dx.doi.org/10.1007/s00271-003-0085-3.
» http://dx.doi.org/10.1007/s00271-003-0085-3

[32] Lesschen, J. P., Velthof, G. L., Vries, D. E. W., and Kros, J. (2011). Differentiation of nitrous oxide emission factors for agricultural soils. Environmental. Pollution, 159, 3215-22. http://dx.doi.org/10.1016/j.envpol.2011.04.001.
» http://dx.doi.org/10.1016/j.envpol.2011.04.001

[33] Lindsay, W. L. and Norvell, W. A. (1978). Development of a DTPA soil test for zinc, iron, manganese and copper. Soil Science Society of America Journal, 42, 421-428. http://dx.doi.org/10.2136/sssaj1978.03615995004200030009x.
» http://dx.doi.org/10.2136/sssaj1978.03615995004200030009x

[34] Malik, R. S., Kumar, K. A. and Bhandar, I. (1994). Influence of nitrogen application by drip irrigation on nutrients availability in soil and uptake by pea. Journal of the Indian Society of Soil Science, 44, 508-509.

[35] Mohammad, M. J. (2004). Utilization of applied fertilizer nitrogen and irrigation water by drip-fertigated squash as determined by nuclear and traditional techniques. Nutrient Cycling in Agroecosystems, 68, 1-11. http://dx.doi.org/10.1023/B:FRES.0000012229.61906.6c.
» http://dx.doi.org/10.1023/B:FRES.0000012229.61906.6c

[36] Moon, D. and Gulik, W. V. (1996). Irrigation scheduling using GIS. Proceedings of the International Conference on Evapotranspiration and Irrigation Scheduling; San Antonio, USA.

[37] Moran, R. (1982). Formulae for determination of chlorophylls pigment extracted with N-N-dimethyl-formamid. Plant Physiology, 69, 1376-1381.

[38] Navid, R., Jahanfar, D. and Hossein, A. F. (2009). Effects of nitrogen fertilizer and irrigation regimes on seed yield of calendula (Calendula officinalis L.). Journal of Agricultural Biotechnology and Sustainable Development, 1, 24-28.

[39] Nielsen, D. C. and Nelson, N. O. (1998). Black bean sensitivity to water stress at various growth stages. Crop Sciences, 38, 422-427.

[40] Nunez-Barrious, A. (1991). Effect of soil water deficits on the growth and development of dry beans ( Phaseolus vulgaris L.) at different stages of growth (PhD thesis). East Lansing: Michigan State University.

[41] Papadopoulos, I. (2000). Fertigation: present and future prospects. In J. Ryan (Ed.), Plant nutrient management under pressurized irrigation systems in the Mediterranean Region (p. 232-245). Amman: ICARDA.

[42] Rathore, S. V. S., Dera, D. K. and Chand, U. (1985). Studies of nitrogen nutrition through foliar spray of urea on the performance of African marigold. Udyarika, 5, 37-40.

[43] Reilly, A. (1978). Park's success with seeds. Green Wood: George W. Park Seed Company.

[44] Richards, L. A. (1954). Diagnosis and improving of saline and alkaline soils. U.S., Salinity Laboratory Staff. Agriculture Handbook, N^o 60.

[45] Washington: USDA; [accessed 2015 Oct. 21]. http://www.ars.usda.gov/sp2UserFiles/Place/20360500/hb60_pdf/hb60complete.pdf
» http://www.ars.usda.gov/sp2UserFiles/Place/20360500/hb60_pdf/hb60complete.pdf

[46] Singh, R. A. (1980). Soil physical analysis. New Delhi: Kalyani Publisher.

[47] Stofella, P. J. and Kahn, B. A. (2001). Compost utilization in horticultural cropping system. Boca Raton: CRC Press.

[48] Suganya, S. and Sivasamy, R. (2006). Moisture retention and cation exchange capacity of sandy soil as influenced by soil additives. Journal of Applied Sciences Researche, 2, 949-951.

[49] Thompson, T. L. and Doerge, T. A. (1996). Nitrogen and water interactions in subsurface trickle irrigated leaf lettuce. II. Agronomic, economic, and environmental outcomes. Soil Science Society of America Journal, 60, 168-173. http://dx.doi.org/10.2136/sssaj1996.03615995006000010027x.
» http://dx.doi.org/10.2136/sssaj1996.03615995006000010027x

[50] Thompson, T. L., Doerge, T. A. and Godin, R. E. (2000). Nitrogen and water interactions in subsurface drip irrigated cauliflower. I. Plant response. Soil Science Society of America Journal, 64, 406-11.

[51] Tumbare, A. D., Shinde, B. N. and Bhoite, S. U. (1999). Effects of liquid fertilizer through drip irrigation on growth and yield of okra ( Hibiscus esculentus). Indian Journal of Agronomy, 44, 176-178.

[52] Veeraputhiran, R. (2000). Drip fertigation studies in hybrid cotton (PhD thesis). Coimbatore: Tamil Nadu Agricultural University.

Soil depth (cm)	Soil bulk density (g∙cm^-3)	Field capacity (m³∙m^-3)	Wilting point (m³∙m^-3)	Available moisture (m³∙m^-3)	pH	Organic matter (%)	Texture
0 - 30	1.58	0.072	0.015	0.057	8.00	0.60	Sandy
30 - 60	1.65	0.101	0.017	0.084	7.93	0.49	Sandy
60 - 90	1.60	0.062	0.016	0.046	7.65	0.31	Sandy

Treatments		Vegetative growth					Flowering growth
Treatments		Plant height (cm)	Number of branches per plant	Dry weight of shoot (g per shoot)	Dry weight of root (g per root)	Flower diameter (cm)	Number of flowers per plant	Dry weight of flower (g per flower)
Significance level
DIS		NS	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
N		^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
DIS × N		^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
Mean values as affected by irrigation systems
Surface		51.71 ± 1.43b	4.90 ± 1.29b	89.43 ± 2.93b	16.26 ± 1.42b	6.53 ± 0.23b	12.47 ± 1.45b	5.97 ± 1.08b
Subsurface		54.34 ± 2.14a	6.66 ± 1.91a	9702 ± 3.72a	19.52 ± 2.13a	6.71 ± 0.31a	14.93 ± 1.24a	6.43 ± 1.19a
Mean values as affected by N fertilizer rate (kg∙ha^-1)
	N0	49.32 ± 1.01d	4.13 ± 1.06c	84.62 ± 2.67d	12.84 ± 1.92d	4.33 ± 0.52d	9.45 ± 0.96d	5.42 ± 1.51d
	N30	52.53 ± 1.52c	4.93 ± 1.23c	88.91 ± 2.93c	15.92 ± 1.98c	5.47 ± 0.07c	11.37 ± 1.09c	6.52 ± 1.44c
	N60	53.92 ± 1.46b	6.48 ± 1.42b	94.93 ± 4.00b	18.51 ± 3.53b	6.76 ± 0.13b	12.46 ± 1.14b	6.96 ± 1.76b
	N120	56.54 ± 2.14a	7.58 ± 1.51a	104.42 ± 3.67a	22.32 ± 2.54a	6.95 ± 0.12a	14.52 ± 1.22a	7.48 ± 1.62a
SDI	N0	48.54 ± 0.57f	3.57 ± 0.73d	82.45 ± 0.86e	11.25 ± 1.00e	4.27 ± 0.02f	8.42 ± 1.01g	5.32 ± 1.00f
	N30	51.26 ± 1.02e	4.53 ± 1.04cd	86.42 ± 1.16d	14.32 ± 0.98d	5.43 ± 0.06de	10.65 ± 1.19^e	6.93 ± 0.42d
	N60	52.71 ± 0.78d	5.41 ± 1.16c	91.43 ± 1.15c	15.43 ± 0.96	5.65 ± 0.13c	11.76 ± 1.01d	6.26 ± 0.98c
	N120	54.67 ± 1.03bc	724 ± 0.28bc	9744 ± 1.04b	20.16 ± 0.61b	6.85 ± 0.14b	12.84 ± 1.15b	7.53 ± 1.59b
SSDI	N0	50.07 ± 0.76e	4.69 ± 1.13cd	86.81 ± 1.72d	14.34 ± 0.86d	5.34 ± 0.05ef	9.53 ± 1.57f	6.40 ± 1.10e
	N30	53.82 ± 0.42cd	5.52 ± 1.32c	91.43 ± 0.96c	1756 ± 0.99c	6.54 ± 0.11cd	11.62 ± 0.99c	6.94 ± 0.81c
	N60	55.11 ± 0.67b	7.54 ± 0.53ab	98.45 ± 1.14b	21.62 ± 1.11b	6.85 ± 0.12b	13.42 ± 1.04b	7.26 ± 0.53b
	N120	58.42 ± 0.51a	8.91 ± 0.45a	111.37 ± 1.12a	24.54 ± 0.99a	703 ± 0.06a	15.67 ± 0.99a	7.92 ± 1.03a

Treatments		Chemical constitutes
Treatments		Chlorophyll a (mg∙g^-1 of FW)	Chlorophyll b (mg∙g^-1 of FW)	Anthocyanins in flowers (mg∙g^-1)	Reducing sugars (%)	Non-reducing sugars (%)
Significance level
DIS		NS	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
N		^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
DIS × N		^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; FW = fresh weight; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
Mean values affected by irrigation systems
Surface		0.51 ± 0.13b	0.14 ± 0.02b	243.63 ± 3.00b	1.07 ± 0.21b	10.07 ± 1.31b
Subsurface		0.63 ± 0.16a	0.19 ± 0.03a	253.45 ± 8.14a	1.11 ± 0.02a	11.16 ± 1.81a
Mean values affected by N fertilizer rate (kg∙ha^-1)
	N0	0.34 ± 0.07c	0.13 ± 0.02d	242.27 ± 2.20d	1.14 ± 0.01c	9.85 ± 0.45b
	N30	0.54 ± 0.11b	0.16 ± 0.02c	256.65 ± 1.96c	1.17 ± 0.01b	10.46 ± 0.54b
	N60	0.62 ± 0.08ab	0.17 ± 0.03b	251.87 ± 4.77b	1.18 ± 0.01b	11.14 ± 0.63a
	N120	0.74 ± 0.06a	0.20 ± 0.03a	25712 ± 7.90a	1.23 ± 0.03a	12.54 ± 1.15a
SDI	N0	0.31 ± 0.02c	0.11 ± 0.01d	241.52 ± 1.37f	1.15 ± 0.01d	9.58 ± 0.52d
	N30	0.43 ± 0.01bc	0.14 ± 0.01d	245.31 ± 0.78e	1.17 ± 0.01c	10.23 ± 0.33d
	N60	0.53 ± 0.01b	0.15 ± 0.01c	246.65 ± 0.63de	1.18 ± 0.01bc	11.42 ± 0.51c
	N120	0.68 ± 0.02a	0.17 ± 0.01b	249.10 ± 0.72c	1.22 ± 0.01b	12.53 ± 0.53b
SSDI	N0	0.36 ± 0.01c	0.14 ± 0.02d	245.02 ± 0.71e	1.16 ± 0.01cd	10.31 ± 0.65d
	N30	0.66 ± 0.02ab	0.17 ± 0.01cd	248.43 ± 1.23cd	1.18 ± 0.01bc	11.29 ± 0.17cd
	N60	0.70 ± 0.02a	0.21 ± 0.01b	255.12 ± 1.67b	1.21 ± 0.01b	12.52 ± 0.56b
	N120	0.81 ± 0.01a	0.23 ± 0.01a	265.24 ± 1.12a	1.26 ± 0.01a	13.52 ± 1.12a

Treatments		Macronutrients concentration			Micronutrients concentration
Treatments		N (%)	P (%)	K (%)	Fe (mg∙kg^-1)	Mn (mg∙kg^-1)	Zn (mg∙kg^-1)
Significance level
DIS		NS	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
N		^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
DIS × N		^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
Mean values as affected by irrigation systems
Surface		1.24 ± 0.03	0.21 ± 0.02b	2.19 ± 0.08b	26.05 ± 1.87b	15.07 ± 2.13b	19.45 ± 2.01b
Subsurface		1.25 ± 0.02	0.24 ± 0.02a	2.23 ± 0.21a	28.51 ± 3.25a	16.64 ± 3.02a	22.25 ± 4.53a
Mean values as affected by N fertilizer rate (kg∙ha^-1)
	N0	1.22 ± 0.01d	0.21 ± 0.02d	2.19 ± 0.21d	24.63 ± 1.25c	12.51 ± 1.04c	18.38 ± 2.06c
	N30	1.24 ± 0.02c	0.23 ± 0.01c	2.16 ± 0.12c	26.15 ± 1.16b	15.52 ± 1.03b	21.00 ± 1.31b
	N60	1.26 ± 0.01b	0.24 ± 0.01b	2.23 ± 0.16b	2716 ± 1.15b	16.40 ± 1.05b	22.40 ± 1.67b
	N120	1.29 ± 0.01a	0.25 ± 0.02a	2.35 ± 0.17a	30.17 ± 2.83a	19.00 ± 2.18a	26.17 ± 4.41a
SDI	N0	1.21 ± 0.01g	0.20 ± 0.01d	2.08 ± 0.06g	24.00 ± 1.00d	12.00 ± 1.00d	17.65 ± 1.43d
	N30	1.25 ± 0.01e	0.21 ± 0.01c	2.16 ± 0.02e	25.33 ± 0.57cd	15.00 ± 1.00c	19.00 ± 1.00c
	N60	1.26 ± 0.01c	0.22 ± 0.01c	2.24 ± 0.05c	26.33 ± 0.56c	16.00 ± 1.00bc	21.23 ± 1.43c
	N120	1.29 ± 0.01a	0.24 ± 0.01b	2.27 ± 0.03a	28.67 ± 0.57b	17.33 ± 1.15b	22.00 ± 1.00b
SSDI	N0	1.23 ± 0.01f	0.22 ± 0.01c	2.31 ± 0.25f	25.32 ± 1.43cd	13.00 ± 1.00cd	19.00 ± 2.45c
	N30	1.25 ± 0.02d	0.23 ± 0.01bc	2.34 ± 0.11d	27.01 ± 1.00bc	16.00 ± 1.00bc	21.00 ± 1.00bc
	N60	1.26 ± 0.01d	0.24 ± 0.01b	2.63 ± 0.26d	28.00 ± 1.00b	1700 ± 1.00b	23.65 ± 1.23b
	N120	1.31 ± 0.02b	0.26 ± 0.02a	2.64 ± 0.04b	32.65 ± 1.43a	20.65 ± 1.43a	29.23 ± 1.43a

Treatments		Macronutrients concentration			Micronutrients concentration
Treatments		N (mg∙kg^-1)	P (mg∙kg^-1)	K (mg∙kg^-1)	Fe (mg∙kg^-1)	Mn (mg∙kg^-1)	Zn (mg∙kg^-1)
Significance level
DIS		NS	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	NS	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
N		^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
DIS × N		^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.	^* * Significant (p < 0.05); NS = non-significant; DIS = drip irrigation system; N = different nitrogen fertilizer rates; SDI = surface drip irrigation; SSDI = subsurface drip irrigation.
Mean values as affected by irrigation systems
Surface		38.12 ± 2.05b	5.35 ± 1.06b	212.65 ± 11.43b	3.46 ± 0.31	1.16 ± 0.04b	1.11 ± 0.14b
Subsurface		49.27 ± 1.53a	5.85 ± 0.86a	215.57 ± 12.39a	3.65 ± 0.26	1.27 ± 0.07a	1.14 ± 0.15a
Mean values as affected by N fertilizer rate (kg∙ha^-1)
	N0	39.15 ± 1.20c	5.46 ± 0.31d	201.65 ± 4.52d	3.27 ± 0.21c	1.15 ± 0.02d	0.81 ± 0.05c
	N30	42.35 ± 1.17bc	6.19 ± 0.29c	214.84 ± 12.45c	3.23 ± 0.31c	1.16 ± 0.02c	1.14 ± 0.01b
	N60	4761 ± 0.57b	6.82 ± 0.25b	233.50 ± 755b	3.45 ± 0.11b	1.21 ± 0.02b	1.21 ± 0.06a
	N120	49.35 ± 0.74a	8.13 ± 0.60a	242.50 ± 6.85a	3.82 ± 0.11a	1.31 ± 0.06a	1.23 ± 0.02a
SDI	N0	44.31 ± 0.57f	5.23 ± 0.04g	198.00 ± 2.00f	3.32 ± 0.27d	1.13 ± 0.01g	0.91 ± 0.06d
	N30	46.65 ± 0.52e	6.01 ± 0.38f	205.67 ± 2.42e	3.41 ± 0.45cd	1.14 ± 0.01f	1.13 ± 0.01c
	N60	48.31 ± 0.56d	6.76 ± 0.45e	214.67 ± 2.42d	3.67 ± 0.05c	1.16 ± 0.01e	1.16 ± 0.02c
	N120	51.06 ± 1.10c	772 ± 0.26b	224.33 ± 1.43c	3.83 ± 0.02b	1.22 ± 0.02b	1.22 ± 0.02b
SSDI	N0	46.57 ± 1.35e	5.81 ± 0.25e	204.33 ± 1.43e	3.41 ± 0.20cd	1.17 ± 0.01e	0.82 ± 0.03c
	N30 N60	48.63 ± 0.43c 49.67 ± 0.57b	6.68 ± 0.46d 706 ± 0.15c	225.00 ± 1.00c 231.31 ± 1.16b	3.42 ± 0.16bc 3.72 ± 0.11b	1.19 ± 0.01d 1.21 ± 0.03c	1.17 ± 0.01bc 1.25 ± 0.05b
	N120	52.65 ± 0.56a	8.23 ± 0.67a	235.657 ± 2.06a	4.21 ± 0.10a	1.33 ± 0.01a	1.26 ± 0.01a

Brasil

Brasil

Impacts of fertigation via surface and subsurface drip irrigation on growth rate, yield and flower quality of Zinnia elegans

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History

EC (dS∙m^-1)	pHw	SAR	Soluble cations and anions (mEq∙L^-1)
			Cations				Anions
			Ca²⁺	Mg²⁺	Na⁺	K⁺	CO3^-	HCO₃^-	Cl^-	SO₄^2-
0.45	7.82	2.7	1.0	0.4	2.3	0.2	-	0.1	2.6	1.3