Economic Performance and Nutrient Use Efficiency of Onion (Allium Cepa L.) Under N, K and S Nutrient Combinations in Northern Ethiopia
RESEARCH ARTICLE

Economic Performance and Nutrient Use Efficiency of Onion (Allium Cepa L.) Under N, K and S Nutrient Combinations in Northern Ethiopia

The Open Agriculture Journal 28 Nov 2019 RESEARCH ARTICLE DOI: 10.2174/1874331501913010146

Abstract

Background:

Nitrogen (N), potassium (K) and sulfur (S) nutrient elements play an important role in the growth and bulb yield of onion. However, imbalanced nutrient application leads onion producers to get lower onion bulb yield. Hence, the supply of adequate and balanced plant nutrients is important in order to achieve better nutrient utilization as well as proper growth and high yield.

Objective:

To evaluate the agronomic and economic performance as well as nutrient efficiency of onion in response to the combined application of nitrogen, potassium and sulfur nutrient levels.

Method:

The field experiment was conducted during 2016/17 to test agronomic, economic and nutrient use efficiency of eighteen treatment groups with the combination of three levels of N, three levels of K and two levels of S nutrient on onion using a randomized complete block design.

Results:

The combined application of N, K and S nutrient levels appreciably resulted in significant variation not only on growth and bulb yield of onion but also on the economic performance and nutrient use efficiencies. Increased growth and improved bulb yield of onion as well as better nutrient uptakes and recoveries were observed in plots treated with relatively higher NKS rates. However, enhanced Agronomic Efficiency (AE) and Partial Factor Productivity (PFP) were obtained from plots treated with no N and K nutrient applications.

Conclusion:

Higher growth, improved bulb yield and enhanced nutrient use efficiencies (nutrient concentrations, uptakes and recoveries) were obtained from onion plants cultivated using a relatively higher NKS nutrient level. However, from the economic point of view, onion production using combined application of 69 kg N ha-1 and 15 kg S ha-1 was the most profitable, irrespective of the K level.

Keywords: Onion growth, Bulb yield, Nutrient uptake, Nutrient concentration, AE, PFP, Apparent Nutrient Recovery (ANR).

1. INTRODUCTION

Onion (Allium cepa L.) is essentially produced by smallholder farmers as a source of income and it is believed to be more frequently consumed than any other vegetable crops in Ethiopia. Though it is an extremely important vegetable crop for internal consumption and income, the national average bulb yield of onion is very low, not more than 10 Mg ha-1 [1] compared to world average productivity, 19.1 Mg ha-1 [2]. Some of the reasons for the low bulb yield of onion are: Lack of high yielding varieties as well as poor management practices including improper fertilizer application. Because of its shallow root system, onion requires high level of soil fertility for high yield [3]. Many scholars reported that growth and bulb yield of onion responded positively to the combined application of NS [3, 4]; NK [5-7]; and NKS [8] nutrients at different doses. One of the crucial reasons for the combined application of nutrients is for boosted bulb yield of onion. Moreover, the amount of nutrients exploited in the harvested portion of a crop depends on the yield and the concentration of the nutrients in the soil. Though nitrogen NKS are essential nutrient elements that play an important role for proper growth and higher bulb yield of onion in the study area, blanket recommendations of only 100 kg Urea and 100 kg DAP (Di Ammonium Phosphate) were used, as sources of N and P; respectively, with no K and S nutrient applications. This imbalanced nutrient application lead onion producers to get lower onion bulb yield. Although the supply of adequate and balanced plant nutrients is important in order to achieve better nutrient utilization as well as proper growth and high yield, little information is available regarding the NKS nutrient requirements of onion in Northern Ethiopia, particularly in the study area. Therefore, the present study was aimed to evaluate onion performance (agronomic and economic) and nutrient use efficiency as affected by the combined application of NKS nutrient levels.

2. MATERIALS AND METHODS

2.1. Description of the Study Area

An experiment was conducted in Tahtay-Koraro district, Northern Ethiopia during 2016/17 under irrigation in the season to examine responses of onion to the combined applications of NKS nutrient levels sourced from mineral fertilizers. The experimental area is situated at 13°88’36” N latitude and 38°04’30” E longitude at an altitude of 1905 meters above sea level. The long term mean annual rainfall of the study area for the past 20 years (1997-2016) was 1050 mm with an average minimum and maximum temperature of 14.18°C and 27.7°C, respectively [9]. According to the modern climatic zone classifications of Ethiopia [10], the study area belongs to the cool sub-humid agro-climatic zone.

2.2. Experimental Design and Treatment Combinations

Optimum nutrient requirements of onion have been reported as 95 to 150kg N and 42 to 133kg ha–1 K [11-13] and 20-40kg S ha–1 [14] being mineral fertilizer sourced. Accordingly, onion variety ‘Neptune’ was used as a test crop in response to eighteen treatment groups with the combination of three levels of N (0, 69, 92 kg ha-1), three levels of K (0, 45, 67 kg ha-1), and two levels of S (0 and 15 kg ha-1) using a randomized complete block design with three replications. Plot size of 2m x 2.1m (4.2m2) was used with a distance of 0.5 m and 1m between plots and replications/blocks, respectively. Urea (46%N) was used for treatments allotted to N only. And for treatments that received N and S combinations, ammonium sulphate (21%N and 23% S) and urea were used. On the other hand, urea and potassium chloride (48.18%K) were applied to treatments that received combined N and K levels. Whereas, potassium chloride was used for the treatments allotted to K alone. For the combined application of K and S, potassium chloride and potassium sulphate (44.55%K, 18.8%S) were used. Sodium sulphate (22.6%S) was used for treatments which required only S. All these mineral fertilizers were applied in band ones after onion seedlings have been transplanted and established well, except urea, which was applied in parts, half was applied just after seedlings get established and the other half was applied 30 days after seedling establishment. The seedlings were transplanted after 48 days from sowing, at a spacing of 10 cm and 30 cm between plant and row, respectively. The crop water requirement (ETc) over the growing season was estimated from the crop coefficient (Kc) and potential evapotranspiration of the study area as ETc=Kc*ETo; and irrigation scheduling was estimated from climatic, soil and crop data using the CROPWAT software. Soil bunds were made around the edges of each plot to prevent nutrient movement across plots.

2.3. Soil and Plant Sample Collection and Analysis

As indicated in the reports by Lee et al. [15], onions have a shallow, sparsely branched root system with most roots in the top 30 cm of soil. Therefore, before the time of onion transplanting, two composite soil samples were taken at a depth of 0-15 cm and 15-30 cm from 17 sampling points to analyze the chemical and physical property of the experimental soil. Routine procedures described in the soil and plant laboratory manual by Sahlemedhin and Taye [16], were followed to determine the selected soil characteristics and plant tissue analysis. Ten randomly selected onion bulb samples were picked from each plot for the analysis of NKS nutrient content at full maturity (95 days after transplanting).

2.4. Agronomic Data Collection and Nutrient Use Efficiency (NUE) Determinations

The average reading of ten randomly selected onion plants from each plot was used for measuring plant height (cm), leaf number and leaf area (cm2) at physiological maturity (65 days after transplanting), and the average values were computed for further analysis. Plant height (cm) of onion plants was measured from the soil surface to the top of the longest leaf using a ruler. Leaf area was measured using a non-destructive estimation method described by Corcoles et al. [17]. After onion was harvested and cured, (95 days after transplanting) mean fresh bulb weight (g) and horizontal bulb diameter (cm) of ten randomly selected bulbs were measured using electronic sensitive balance and a caliper, respectively. In addition to this, ten chopped onion bulb samples were dried in an oven at 72°C for 48 hours until a constant weight was obtained and average dry-bulb weight (g) was measured using the electronic sensitive balance. However, total bulb yield from a net plot size of 1.8 m2 was measured in kilograms using a scaled balance and expressed in Mg ha-1.

Nutrient Use Efficiency (NUE) of every treatment was analyzed using the following common NUE measurements and calculations written by Doberman [18].

Partial Factor Productivity (PFP) =

Nutrient uptake =

Agronomic Efficiency (AE) =

Apparent Nutrient Recovery (%ANR) =

2.5. Economic and Statistical Data Analysis

The partial budget analysis was carried out based on CIMMYT [19], to evaluate the economic performance of onion under combined application of NKS nutrient levels by estimating the varying costs and returns based on market prices for 2016. Gross returns, net returns and marginal rate of return were calculated using the following formulas.

Gross return=bulb yield*price

Net return=gross return-total varying cost

Marginal Rate of Return (MRR)=

The varying fertilizer and labor costs were estimated based on the existing rate of fertilizer purchase and daily labor payment. Costs that do not vary among all treatments were excluded in the analysis. The Marginal Rate of Return (MRR) analysis was carried out on both dominated and non-dominated treatments in a stepwise manner. As suggested by most scholars, 100% minimum rate of return was considered as a guarantee for the farmers to accept or to reject alternative fertilization without a doubt.

The collected data on onion growth and yield parameters were subjected to the analysis of variance procedure with the help of SAS JMP-5 software. Treatment shows that separation was carried out using Tukey’s HSD test at 1% probability level.

3. RESULTS

3.1. Soil: Physical and Chemical Properties of the Experimental Site

The physical and chemical property of the study site before onion seedling transplantion is displayed in Table 1. Based on FAO/UNESCO [20], soil map, soil type of the experimental area was vertisol with a textural class of silt clay loam. Laboratory analysis of the experimental soil showed that the soil was non-saline with neutral pH and low organic content matter (Table 1). Values of the soil parameters decreased across depths except, available K and pH level, which showed a relative increase with depth. Besides, the nutrient status of the experimental soil prior to the transplantion of onion seedlings was low in both soil depths, except the concentration of phosphorus which was rated as high according to Havlin et al. [21]. As a result, onion is expected to respond to NKS nutrient application doses.

3.2. Growth of Onion as Affected by NKS Nutrient Levels

The result presented in Table 2 shows that the growth parameters of onion were strongly affected by the combined application of NKS nutrient levels at 0.01 significance levels. Considerably higher onion plant height (57.06 cm) was recorded in plots treated with N92S15K67. This result is closely followed by 56.57 cm and 56.13cm recorded from N92S15K45 and N92S15K0 treatments, respectively.

The result in Table 2 depicted that, the maximum number of leaves per plant were observed from the higher NS nutrient levels (N92S15) with low (K0 ) to medium (K45) K levels. Whereas, minimum number of leaves per plant (8.01) were observed in control treatment (N0 S0 K0 ).

Similar to the plant height and leaf number, leaf area was higher (853.20 cm2) in plots treated using N92S15K67 while lower (307.10 cm2) was recorded in the control treatment (N0 S0 K0 ).

3.3. Bulb Yield and Yield Attributes of Onion as Affected by NKS Nutrient Levels

As indicated in Table 3, onion bulb yield and yield-related parameters have notably been influenced by NKS nutrient levels at 1% probability level. Noticeably, a higher bulb diameter, 8.64 cm was recorded from plots treated with N92S15K67 nutrient doses. This result is followed by 8.54 cm and 8.43 cm which were recorded from plots which received N92S15K45 and N92S15K0 , respectively. Onion bulb diameter obtained from the application of N92S15K67 nutrient levels was 117.09% higher than the bulb diameter measured from the control treatment. Besides, fresh and dry onion bulb weights were remarkably affected by the combined application of NKS nutrient levels (Table 3). Higher fresh bulb weight (220.75 g) of onion per plant was recorded from plots treated with N92S15K67 nutrient doses, non-significantly followed by 212.8 g, 206.43 g, and 195.78 g recorded from treatment with N92S0 K67 N92S15K0 and N92S15K45, respectively.

Similar results were reported by Nigatu et al. [3], who recorded maximum bulb weight from the combined use of 105 kg N ha-1 and 22 kg ha-1 S. Fresh weight of onion bulb observed from N92S15K67 was 282.91% higher than the control treatment. Similar to the bulb diameter and fresh weight of onion plants, maximum dry weight (44.70 g) of onion bulb per plant was recorded from plots treated with N92S15K67 nutrient doses, which was 189.51% higher than the control treatment.

The data pertaining to Table 3 showed that the combined application of NKS nutrient levels strongly affected the bulb yield of onion. Increasing NKS nutrient doses significantly increased the total bulb yield of onion. Higher bulb yield of onion, 30.17, 29.11, 28.40 Mg ha-1 were recorded from the treatments that received N69S15K0 , N69S15K45 and N69S15K67, respectively with non-significant difference among them. Bulb yield of these treatments was enhanced by 302.6%, 291.98% and 284.86% over the control treatment. Likewise, higher bulb diameter, fresh bulb weight and dry weight were also observed from these treatments (Table 3). This implies that bulb diameter and bulb weight were the direct contributors to the increase in total bulb yield.

3.4. Nutrient Use Efficiency of Onion Bulb

3.4.1. Nutrient Uptake and Concentration

Fig. (1) presents nitrogen (N), potassium (K) and sulfur (S) concentrations in onion bulb (a-c) and nutrient uptakes by onion bulb (d-e). The combined application of NKS nutrients at different levels significantly affected the nutrient content/ concentration and nutrient uptake of onion bulb at 0.01 significance level. Significantly higher N concentrations, 3.53% and 3.51% in the bulb yield of onion were recorded from N92S15K67 and N69S15K45 treatments, respectively (Fig. 1a). Obviously, lower N concentration (2.64%) was recorded from the control treatment. Similarly, 1.32% and 1.30% of K concentration were obtained from an onion bulb treated with the combined nutrient levels of N92S15K67 and N92S15K45, respectively; which were 21.21% and 20% higher than the K concentration of onion bulb in the control treatment, respectively (Fig. 1b). Maintaining application of 92 kg ha-1 N and 15 kg S ha-1; increasing the application rates of K nutrient from 0 to 45 kg ha-1 and from 0 to 67 kg ha-1 increased K concentration of onion bulb by 11.29% and 16.67%, respectively. Similar to the N and K nutrient concentrations, S nutrient concentration in the bulb of onion was strongly influenced by combinations of NKS nutrient levels (Fig. 1c).

In this study, relatively better S content (0.55%, 0.52, and 0.51%) in the bulb of onion was recorded from N69S15K67, N69S15K0 and N69S15K45 treatments, respectively. This implies that the application of S nutrient in combination with N and K enhanced the uptake of S. This lower S content in the bulb yield of onion was recorded from the control treatment. Sulfur content in the bulb of onion was affected more by N and S nutrient application levels rather than by K.

Linear increase of nutrient uptake was obtained with increasing NKS nutrient levels as is indicated in Figs. (1d-f). The result presented in Fig. (1d) signifies that better N uptakes (106.58 kg ha-1 and 102.07 kg ha-1) were recorded from N92S15K45 and N92S15K67 nutrient application rate, respectively. This result is followed by the uptake of 93.43 kg ha-1 N, which was recorded from N92S15K0 nutrient levels. N uptake was lower (26.31 kg ha-1) in the control treatment. Application on N in combination with K and/or S nutrients enhanced the N uptake of the onion bulb. Correspondingly, higher plant N uptake was recorded from combined N and S fertilization [4, 22, 23]. Comparable to N uptake, better K uptakes (39.73 kg ha-1 and 36.06 kg ha-1) were recorded from N92S15K45-67 nutrient application rates, closely followed by 34.36 kg ha-1, which was observed from N92S0 K67 (Fig. 1e). Lower K uptake was observed from the control treatment. This indicates that application of N and S nutrient combination facilitated the uptake of K by the onion bulb. Equivalent to N and K uptakes, higher (16.59 kg ha-1) and lower (3.52 kg ha-1) S uptakes were observed on plots treated with N92S0 K67 and N0 S0 K0 , respectively (Fig. 1f). The application of 15 kg ha-1 S in combination with 92 kg N ha-1 and 67 kg K ha-1 increased S uptake by 292.59% rather than the sole application of S at 15 kg ha-1 rate.

3.4.2. Agronomic Efficiency (AE), Partial Factor Productivity (PFP) and Apparent Nutrient Recovery (ANR)

(Fig. 2) presents the combined effect of NKS nutrient levels on AE and PFP. The combined application of NKS nutrient levels significantly affected AE and PFP at 1% probability level. Better AE (202.22 and 172.24 kg bulb per kg nutrient applied) were observed in plots treated with N0 S15K0 and N92S15K0 , respectively. Potassium nutrient application (without nitrogen and sulfur application) has a low effect on AE (Fig. 2).

Similarly, the highest PFP (906.67 kg bulb per kg nutrient applied) was observed on plots treated with N0 S15K0 nutrient combinations at 1% probability level (Fig. 2). This result is appreciably followed by plots treated with N92S15K0 nutrient combinations, which attained 338.05 kg bulb per kg nutrient .

As the result depicted in (Fig. 3), apparent nutrient recovery was significantly affected by NKS nutrient levels. The highest apparent nitrogen recovery, 71.24% was recorded from N92S15K67 treated plots (Fig. 3a). This result was non-significantly followed by 63.94% and 60.29% which were recorded from N92S15K45 and N92S15K0 treated plots, respectively. This indicates that irrespective of nitrogen and sulfur nutrient levels, decreasing potassium nutrient levels notably decreased apparent nitrogen recovery. Comparable to the apparent nitrogen recovery, the combined use of NKS nutrient levels extensively influenced apparent potassium recovery at 1% significance level (Fig. 3b). The highest apparent potassium recovery (11.75%) was recorded from N92S15K67 treatment followed by 9.33% and 8.97% which were recorded from N92S15K45 and N92S0 K67 treatments, respectively. Lower apparent potassium recoveries were recorded from lower NKS nutrient levels.

The result in (Fig. 3c) revealed that significantly higher apparent sulfur recoveries (46.43% and 40.02%) were recorded from N92S15K67 and N92S15K45 treatments, respectively. Increasing nitrogen and potassium nutrient levels have markedly increased apparent sulfur recovery. Apparent sulfur recovery was markedly influenced by the change in nitrogen level than the potassium level.

3.5. Economic Performance Analysis

The result of economic performance of the treatments analyzed using partial budget method (Table 4) shows that higher Marginal Rate of Returns (MRR), 2258.01% and 2073.98% were recorded in N92S15K0 and N92S0 K0 treated plots. However, net field incomes are different from profits because in the partial budget analysis, only variable costs are considered excluding the other production costs. Thus, based on the size of the net field incomes, it would be difficult to select the economically preferred treatment. For this reason, in order to compare each treatment, dominance analysis was performed based on the information on net field benefits and costs that vary (Table 5).

Accordingly, the stepwise comparison (dominance analysis) between successive treatments (Table 5) depicted that higher MRR, 61087.55%, 61721.14%, and 62354.74% were recorded from experimental plots treated with N69S15K45, N69S0 K0 , and N69S15K0 nutrient combinations. The dominance analysis (Table 5) showed that only twelve NKS nutrient combinations were not dominated while the six nutrient combinations are dominated treatments and they have no profit.

Therefore, considering the assumption of minimum acceptable MRR by farmers to be 100% to adopt new fertilizer combinations, onion production with 69 kg N ha-1 combined with or without K and S was acceptable. The dominance analysis result displayed in Table 5 revealed that the most profitable nutrient combinations are ranked as N69S15K0 > N69S0 K0 > N69S15K45.

Fig. (1). Nutrient concentration (%) and uptakes (kg ha-1) of onion bulb: Nitrogen concentration (a), Potassium concentration (b), Sulfur concentration (c), Nitrogen uptake (d), Potassium uptake (e), Sulfur uptake (f). Treatments (column) not connected by same letter for nutrient concentrations and uptakes are significantly different at the 0.01 level of probability. Vertical bars represent standard error of the mean.
Table 1.
Soil characteristics of the experimental area before onion seedling transplantion.
Parameters Soil Depth (cm)
0-15 16-30
Total N (%) 0.084 0.075
Available K (ppm) 33.2 38.4
Available S (ppm) 6.4 5.8
Available P (ppm) 16.8 12.7
OC (%) 0.81 0.71
OM (%) 1.4 1.22
pH (1:2.5 water) 6.67 6.8
EC (ds/m) 0.17 0.08
OC: organic carbon; OM: organic matter; EC: electronic conductivity.
Table 2.
Onion growth parameters as affected by nitrogen, potassium and sulfur nutrient levels.
Nutrient Levels (Treatments) Plant Height (cm) Nº of Leaves Per Plant Leaf Area (cm2)
N0 S0 K0 (control) 40.96l 8.01g 307.10m
N0 S0 K45 40.41lm 7.98g 313.48m
N0 S0 K67 39.94m 8.21g 352.39lm
N0 S15K0 42.95k 9.36f 403.29klm
N0 S15K45 43.39k 9.44f 424.71jkl
N0 S15K67 44.39j 9.55f 454.76ijk
N69S0 K0 46.84i 10.94e 495.00hij
N69S0 K45 47.34i 11e 515.96ghi
N69S0 K67 48.34h 11.12e 544.93fgh
N69S15K0 51.09g 12.56d 599.02efg
N69S15K45 51.63fg 12.58d 618.92def
N69S15K67 52.30ef 12.76d 651.50cde
N92S0 K0 53.00de 13.27c 695.02cd
N92S0 K45 53.46cd 13.34c 717.98c
N92S0 K67 54.14c 13.46c 731.82bc
N92S15K0 56.13b 14.59ab 738.53bc
N92S15K45 56.57b 14.70a 819.09b
N92S15K67 57.06a 14.14b 853.20a
CV 11.67 1.96 9.84
Significance level ** ** **
Treatments not connected by the same letter for a growth or yield parameter are significantly different at 99% probability level. ** stands significant at P<0.01.
Table 3.
Onion yield parameters as affected by nitrogen, potassium and sulfur nutrient levels.
Nutrient Levels (Treatments) Bulb Diameter (cm) Fresh Bulb Weight (g) Dry Bulb Weight (g) Total Bulb Yield (Mg ha-1)
N0 S0 K0 (control) 3.98m 57.65l 15.44h 9.97k
N0 S0 K45 4.05m 59.54l 15.79h 10.90k
N0 S0 K67 4.23lm 69.75kl 17.15gh 12.10jk
N0 S15K0 4.80klm 84.53jkl 18.18gh 13.60ij
N0 S15K45 5.68jkl 89.51jkl 19.04gh 15.50i
N0 S15K67 5.02kl 98.13ijk 20.65g 14.72ij
N69S0 K0 5.78ijk 120.27hij 26.37f 18.31h
N69S0 K45 5.88hij 126.12ghi 27.35f 18.90h
N69S0 K67 6.1ghij 135.59fgh 28.76f 19.90gh
N69S15K0 6.6fghi 156.27efg 34.67e 21.80fg
N69S15K45 6.72fgh 157.82efg 35.71de 22.53ef
N69S15K67 6.85efg 166.04def 37.11de 23.60def
N92S0 K0 7.57def 175.28cde 36.92de 25.00cde
N92S0 K45 6.68cde 180.85bcde 37.92cde 25.51cd
N92S0 K67 7.82bcd 212.8ab 39.32bcd 26.50bc
N92S15K0 8.43bc 206.43abc 42.30abc 28.40ab
N92S15K45 8.54b 195.78abcd 43.22ab 29.11ab
N92S15K67 8.64a 220.75a 44.70a 30.17a
CV 4/24 8.60 7.71 5.87
Significance level ** ** ** **
Treatments not connected by the same letter for a growth or yield parameter are significantly different at 99% probability level. ** stands significant at P<0.01.
Fig. (2). Agronomic efficiency (Kg bulb / kg nutrient) and partial factor productivity (Kg bulb / kg nutrient). Treatments (columns) not connected by the same letter for AE and PFP are significantly different at the 0.01 level of probability. Vertical bars represent standard error of the mean.
Fig. (3). Apparent nutrient recovery (%) of nitrogen (a), potassium (b) and sulfur (c). Treatments (columns) not connected by the same letter for apparent recovery of N, K and S are significantly different at the 0.01 level of probability. Vertical bars represent standard error of the mean.
Table 4.
Marginal Rate of Return (MRR) analysis in comparison with control treatment (NoS0 K0 ).
Nutrient Levels (Treatments) Returns and Costs in USD
Gross Return Total Varying Cost Net Return Net Income Over Control MRR (%)
N0 S0 K0 (control) 4609.71 0.00 460.97 - -
NoS0 K45 4930.62 454.68 4475.93 4014.96 883.03
NoS0 K67 5390.29 526.95 4863.33 4402.36 835.43
NoS15K0 6027.75 410.27 5617.49 5156.52 1256.87
NoS15K45 6461.41 482.54 5978.87 5517.89 1143.51
NoS15K67 6838.68 554.81 6283.87 5822.90 1049.53
N69S0 K0 7892.45 459.47 7432.98 6972.01 1517.39
N69S0 K45 8196.01 531.75 7664.26 7203.29 1354.65
N69S0 K67 8642.67 604.02 8038.65 7577.68 1254.54
N69S15K0 9453.60 487.33 8966.27 8505.30 1745.28
N69S15K45 9770.16 559.60 9210.56 8749.59 1563.53
N69S15K67 10234.17 631.88 9602.29 9141.32 1446.69
N92S0 K0 10784.91 474.89 10310.02 9849.05 2073.98
N92S0 K45 11058.11 547.16 10510.95 10049.98 1836.76
N92S0 K67 11491.76 619.43 10872.33 10411.36 1680.79
N92S15K0 12315.70 502.74 11812.95 11351.98 2258.01
N92S15K45 12619.25 575.02 12044.24 11583.27 2014.42
N92S15K67 13083.26 647.29 12435.97 11975.00 1850.02
Table 5.
Dominance analysis.
Treatments Returns and Costs in USD
Gross Return Total Varying Cost Net Return Net Income Over Control Marginal Rate of Return (%)
N0 S0 K0 4609.71 - 460.97 - -
N0 S15K0 6027.75 410.27 5617.49 5156.52 1256.87
N0 S0 K45 4930.62 454.68 4475.93 4014.96 -2570.17
N69S0 K0 7892.45 459.47 7432.98 6972.01 61721.14
N92S0 K0 10784.91 474.89 10310.02 9849.05 18666.53
N0 S15K45 6461.41 482.54 5978.87 5517.89 -56587.25
N69S15K0 9453.60 487.33 8966.27 8505.30 62354.74
N92S15K0 12315.70 502.74 11812.95 11351.98 18469.58
N0 S0 K67 5390.29 526.95 4863.33 4402.36 -28703.67
N69S0 K45 8196.01 531.75 7664.26 7203.29 58462.64
N92S0 K45 11058.11 547.16 10510.95 10049.98 18469.58
N0 S15K67 6838.68 554.81 6283.87 5822.90 -55227.48
N69S15K45 9770.16 559.60 9210.56 8749.59 61087.55
N69S15K45 12619.25 575.02 12044.24 11583.27 18385.17
N45S0 K67 8642.67 604.02 8038.65 7577.68 -13811.12
N92S0 K67 11491.76 619.43 10872.33 10411.36 18385.17
N69S15K67 10234.17 631.88 9602.29 9141.32 -10205.23
N92S15K67 13083.26 647.29 12435.97 11975.00 18385.17
Values in bold indicate dominated treatment

4. DISCUSSION

Onion plant height, leaf number and leaf area were strongly affected by the combined applications of NKS nutrient levels (Table 2). A similar result was also reported by Nasreen et al. [4] and Nigatu et al. [3]. Significantly shorter plant height, minimum number of leaves and lower leaf area of onion were recorded from plots treated with lower NS nutrient levels, despite K nutrient dose. On the other hand, superior onion growth performance was observed under the combinations of higher nutrient levels. Despite the K nutrient level, any changes in N and S nutrient levels significantly affected growth (plant height, number of leaves per plant and leaf area) and yield performance of onion. The mean height of onion treated with N92S15K67 nutrient levels was 28.22% superior than the height of onion plants in the control treatment (N0 S0 K0 ). Similarly, onion plants cultivated under N92S15K67, N92S15K45 and N92S15K0 nutrient levels were 45.35%, 45.51% and 45.10% higher in leaf number than the control treatment, respectively. Increasing K nutrient level from 45 kg ha-1 to 67 kg ha-1 at higher NS nutrient application levels (92 kg ha-1 N and 15 kg ha-1 S) decreased leaf number in onion plants by 3.96%. Conversely, at lower NS nutrient levels, changing K nutrient levels had no significant effect on leaf number of onion (Table 2). Furthermore, at the lower doses of N and/or S nutrients, K nutrient has a low effect on onion leaf area.

In the present study, increasing the application of NKS nutrient levels increased onion bulb diameter, bulb weight and total bulb yield (Table 3). Higher bulb diameter, fresh bulb weight and dry bulb weights of onion were recorded from N92S15K67, N92S15K45 and N92S15K0, ranked in decreasing order. However, at relatively lower rates of N and/or S nutrient levels (below 92 kg ha-1 N and/or 15 kg ha-1 S), onion bulb yield and yield-related parameters showed a low response to K application levels. This implies that onion plants need relatively more N and S, than K. Moreover, the present study showed that onion bulb yield has strong response to higher N and S levels than K nutrient, indicating that the combination of maximum level of N (92 kg ha-1) and S (15 kg ha-1) had improved the productivity of onion, irrespective of K nutrient dose which appears to be weakly associated. These results are further supported by the literatures [3-5]. Onion growth and bulb yield increased by linearly increasing NKS nutrient application rates at higher than 0 kg ha–1 (Tables 2 and 3). The results of this study are in agreement with Nigatu et al. [3] and Nasreen et al. [4].

Noticeably higher concentrations of N (3.53% and 3.51%) and K (1.32% and 1.30%) in the bulb yield of onion were recorded from N92S15K67 and N69S15K45 treatments with a non-significant difference between them, respectively. Whereas, enhanced S concentration (0.55%, 0.52% and 0.51%) were observed from N92S15K67, N92S15K0 and N69S15K45 treatments with the insignificant differences among them, respectively. Mishu et al. [14] recorded maximum sulfur content (0.49%) of onion bulb at 40 kg S ha-1 followed by 0.45% at 20 kg S ha-1 application level. As indicated in Figs. (1d-f), combined and increased application of NKS nutrient levels linearly increased the nutrient uptake of the onion bulb. The findings of Habtegebrial, Singh [23] and Nasreen et al. [4] confirmed that significantly higher plant N uptake was recorded due to the combined N and S fertilization. Obviously, lower NKS nutrient concentrations and uptakes in the bulb of onion were recorded from the control treatment.

The result depicted in Fig. (2) showed that appreciably highest AE (242.22 kg bulb per kg nutrient applied) and PFP (906.67 kg bulb per kg nutrient applied) were observed on plots treated with no NK nutrient combinations (N0 S15K0 ). The mean AE in plots treated with N0 S15K0 was 28.89% and 54.55% higher than the next ranked treatments, N92S15K0 and N69S15K0 , respectively. This implies that the influence of sulfur nutrient on AE was greater than that of nitrogen. On the other hand, the average AE in N0 S15K0 was 162.65% and 318.13% higher than in N0 S15K45 and N0 S15K67 treated plots, respectively. At 0 kg ha-1N and 15 kg ha-1S levels, AE decreased with increasing potassium nutrient level from 45 kg ha-1 to 67 kg ha-1. At higher nitrogen and potassium nutrient levels (N92S15), increasing potassium nutrient levels from zero to 45 kg ha-1 and from zero to 67 kg ha-1 decreased PFP by 26.89% and 32.56%, respectively. This implies that AE is less affected by potassium nutrient application.

Onion production with the combined application of NKS nutrient at different levels significantly influenced apparent nutrient recovery (Fig. 3). Better N, S and K recovery were recorded from the experimental plots treated with N92S15K67 (Fig. 3) which might be probably due to the presence of one or more nutrient combinations that can facilitate the uptake of one or the other nutrient. Habtegebrial and Singh [24] reported that S application along with N improves the N use efficiency by 28%. Cassman et al. [25] also reported that N recovery from mineral fertilizers is about 33- 50%. However, in the present study, maximum apparent N recovery was 71.24% higher than the cited reports.

Despite K and S nutrient levels, better MRR was observed at a high nitrogen level (92 kg ha-1 N). Comparable results were also reported by Nigatu et al. [3], who obtained higher MRR at 105 kg ha-1 N and 16.95 kg ha-1 S. However, based on the dominance analysis, higher MRR, 62354.74% was recorded from N69S15K0 nutrient combination. This entails that, by applying 69kg ha-1 N combined with 15 kg ha-1 S, farmers can recover 1 USD plus an extra 623.55 USD ha-1 in a net benefit for each 1 USD ha-1 on average.

CONCLUSION

Higher growth, bulb yield, and nutrient use efficiency were recorded when an onion is cultivated using N92S15K67 nutrient combination. An increasing trend in growth, bulb yield and yield-related parameters of onion was observed with increasing NKS nutrient concentrations, especially at higher nitrogen and sulfur levels. Application of NKS nutrient combinations enhanced nutrient concentration nutrient uptake of the onion bulb. Superior AE and PFP were observed in plots treated with N0 S15K0 . Unlike the AE and PFP, better nutrient content, nutrient uptake and apparent nutrient recoveries were recorded from the combined nutrient application at higher levels (N92S15K67), whereas inferior nutrient utilization efficiencies were observed on the control treatment (N0 S0 K0 ). The low response of the control treatment in almost all the parameters can be attributed to the low fertility status of the experimental soil. The present study reveals that the combined application of NSK at a ratio of 92:15:00-67 kg ha-1 is an adequate dose for proper growth and yield performance of onion. Conversely, there have been various reports, of NKS nutrient levels as high as this dose showing significant yield increase. However, from the economic point of view, onion production using 69 kg N ha-1 and 15 kg S ha-1 nutrient combinations was the most profitable, irrespective of the K level.

ETHICS APPROVAL AND CONSENT TO PARTICIPATE

Not applicable.

HUMAN AND ANIMAL RIGHTS

No animals/humans were used for studies that are the basis of this research.

CONSENT FOR PUBLICATION

Not applicable.

AVAILABILITY OF DATA AND MATERIALS

Not applicable.

FUNDING

None.

CONFLICT OF INTEREST

The author declares no conflict of interest, financial or otherwise.

ACKNOWLEDGEMENTS

Declared none.

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