Response of Some Sugarcane Cultivars to Nitrogenous Fertilization and Micronutrients on Productivity and Quality

Khalifa Hashem, Ahmed Fathy; Radwan, Fathy Ibrahim; Gomaa, Mahmoud; Hussein, Magda Abo ElMagd; El-Taib, Ashraf Bakry

doi:10.21608/jalexu.2016.195616

Response of Some Sugarcane Cultivars to Nitrogenous Fertilization and Micronutrients on Productivity and Quality

Journal of the Advances in Agricultural Researches

Article 12, Volume 21, Issue 4 - Serial Number 81, December 2016, Page 712-721 PDF (153.07 K)

Document Type: Research papers

DOI: 10.21608/jalexu.2016.195616

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Authors

Ahmed Fathy Khalifa Hashem¹; Fathy Ibrahim Radwan¹; Mahmoud Gomaa¹; Magda Abo ElMagd Hussein²; Ashraf Bakry El-Taib³

¹Plant Production Dept. Faculty of Agriculture (Saba Basha), Alexandria University

²Soil and Agricultural Chemistry Dept. Faculty of Agriculture (Saba Basha), Alexandria University

³Agronomy Dept. Faculty of Agriculture Aswan

Abstract

Two filed experiments were carried out in the experiment farm of Faculty of Agriculture Aswan Egypt, during 2014 and 2015 growing seasons. The objective of this study was to investigate the response of some sugarcane cultivars to nitrogenous fertilization and micronutrient on productivity and quality. Experimental design was spilt spilt plot with three replicates. The results could be summarized as follows: Giza 9 variety at the four sampling dates had higher cane length, number of tillers/plant, number of internode/plant, leaf area index and cane diameter, also, cane girth, sugar cane, Brix (TSS%), sucrose (%), purity (%) and commercial cane sugar % (CCS%). Addition, nitrogen fertilizer at rate of 200 kg N/fed, resulted in a significant increment in growth characters, yield and quality of sugarcane plants in both seasons. Significant variations were recorded between the tested foliar micronutrient treatments for growth characters, yield and sugarcane quality. The effective treatments for growth characters, yield and quality were obtained for Giza 9 variety and adding 200 kg N/fed in both seasons. The highest values of all growth characters, yield and quality were obtained by Giza 9 variety with using the application of 200 kg N/fed and mixture of Zn +Fe treatment.

Keywords

sugarcane cultivars; nitrogenous fertilizer; micronutrient; growth; yield and quality

Full Text

INTRODUCTION

Sugarcane (Saccharum officinarum L.) is a commercial crop grown in tropical and sub-tropical regions for sugar production in climates ranging from hot dry environment near sea level to cool and moist environment at high elevations (Plaut et al., 2000). Apart from the main product, sugar, it produces many valuable co-products such as alcohol used by pharmaceutical industry and as fuel, bagasse for paper and chip board and press mud as a rich source of organic nutrients for crop production (Kumar et al., 1996 and Legendre et al., 2000).Thrives best a temperature above 20°C and requires a period of about 8 to 24 months to reach maturity (Nazir, 2000). Sugarcane is a major cash crop in Egypt, which not only provides man stay to sugar industry but also, row materials to many allied industries for alcohol and chip broad manufacturing (Naqvi, 2005).

Nitrogen is essential for vigorous vegetative growth and development, yield and quality in sugarcane. It is a constituent of plant cell components e.g. amino acids and nucleic acids and its deficiency inhibits plant growth, reduction in leaf area, thus causes a decrease in photosynthesis hence suppressing yield and quality (Taiz and Zeiger, 2002 and Sreewarome et al., 2007). Application of N fertilization is mandatory in intensive sugarcane cultivation which requires a high amount of nitrogen as a nutrient to produce high biomass (Thornburn et al., 2005). Excess N and low N uptake cause retarded growth phase and decreases photosynthetic capacity of leaves thus causing shorter internodes (Martin, 1994). For many locations the depletion of plant available soil N over time justifies the need for split application of yearly total N rate (Wiedenfeld, 1995).

Micronutrients can be applied directly into the soil or by foliar application. Foliar application has many advantages such as less application rate, even distribution of nutrients and immediate response of plant to applied material. It also, performs better where; soil alkalinity and permeability are more which leads to leaching of nutrients. Foliar application of nutrients is useful where the nutrients are fixed up to in the soil and thereby not available for absorption by the roots. Foliar application of zinc sulphate and iron sulphate increases cane yield (Chandra, 2005 and Boklar and Sakurai, 2005). The aim of this study was to examine the response of some sugarcane cultivars to nitrogenous fertilization and micronutrients on productivity and quality.

MATERIALS AND METHODS

The present study was carried out at the experimental farm Kom-Omb-Aswan, Egypt, sugarcane is grown in the belt 32°N and 24°S, during the two successive growth seasons of 2014 and 2015 seasons to study the response of some sugarcane cultivars to nitrogenous fertilization and micronutrients on productivity and quality. The main physical and chemical properties of cultivated soil before planting and also, its content of some macro and micronutrients were determined according to the methods described byPage et al. (1982)as shown inTable (1)

Table (1). Some Physical and chemical properties of the experimental soil in 2014 and 2015 seasons.

Value			Parameter
Unit	2015	2014	Parameter
			Mechanical Analysis
%	53.00	52.12	Sand
%	23.00	22.00	Silt
%	24.00	22.88	Clay
Sandy Clay Loam			Textural class
-	7.84	7.92	pH (1:2)
%	2.3	2.1	Ca Co₃
dS/m	0.412	0.417	EC(1:2, water extract)
%	1.55	1.65	O.M
			Soluble cations
meq/l	2.02	2.04	Ca²⁺
meq/l	2.99	3.06	Mg²⁺
meq/l	1.42	1.41	Na⁺
meq/l	0.70	0.71	K⁺
			Soluble anions
meq/l	5.2	5.4	HCO3^-
meq/l	7.85	7.82	Cl^-
meq/l	0.77	0.79	SO₄^2-
			Available nutrients
mg/kg	188.4	189.5	Nitrogen (N)
mg/kg	45.80	46.75	Phosphorus (P)
mg/kg	1001	1000	Potassium (K)

A split split plot design with three replicates was used in both seasons. Three cultivars (Giza 9 (V1), Giza 47 (V2) and Giza 49 (V3) were randomly assigned to the main plots, three nitrogen fertilizer levels (120, 160 and 200 kg N/fed) were allocated to sub plots and three micronutrients treatments (Zn, Fe and Zn +Fe) were randomly distributed in sub sub plots.

The experiment was laid out as split split plot with three replicates Net plot size was 4.5m x 8.0 m for 75 cm spaced trenches.

Fertilization

Fertilizers were applied at the rate of 115 kg P₂O₅/ha and 115 kg/ha K₂O, respectively. Phosphorus (single super phosphate 15.5% was applied at the time of sowing and SOP (sulphate Potash, 48 %K₂O). The amount of Zn and Fe was applied at 2kg Zn and 2kg Fe/fed. The foliar spray of 1/3^rd dose of Zn and Fe and mixture Zn + Fe were applied 50 days after sowing and the remaining 2/3 was applied in two equal splits in 20 days intervals after the 1^st spray. The sources of Zn and Fe were Zn SO₄-H₂O (35% Zn) and FeSO₄ - 7H₂O (19.5 % Fe), respectively.

Recorded data

A. Growth attributes

· Cane length (cm)
· Cane diameter (cm)
· Number of tillers/plant
· Number of internods/plant
· Leaf area index

B. Yield

· Cane girth
· Sugar yield (ton/ha) was determined by the following formula:

Sugar yield (t/ha)=

C. Qualitative traits

· Brix %

Ten cane randomly selected from every plot were crushed through a cane crusher and the juice was collected in glass jars. The reading brix (%) was recoded with brix hydrometer. Temperature of the juice was noted. These brix reading were corrected with the help of Schmitz table (Spancer and Meade, 1963).

· Sucrose in juice %

With the help of parameter, pol reading of extracted juice of every treatment was recorded. Sucrose contents of cane juice were calculated with the help of Schmitz table (Spancer and Meade, 1963).

· Cane juice purity %

Cane juice purity was determined at described by (Spancer and Meade, 1963).

Cane juice purity (%) =

· P=Pol % in juice
· B= Brix % in juice
· F=Fiber % in juice (12.5%)
Commerical cane sugar (CCS %) was determined by as per the method described by Meady and Chen (1997).

CCS % = 3/2 (1- ) -1/2 B(1- )

Where S = Sucrose percent in juice

All the data collected were subjected to statistical analysis of Varian ANOVA and (L.S.D.) values to test the differences among the standard treatments means according to Gomez and Gomez (1984).

RESULTS AND DISCUSSION

A. Growth attributes

All the studied growth characters were greatly increased by all treatments with significant differences in most cases.

Regarding sugarcane varieties effect on cane length at all sampling dates and number of tillers/plant, number of internode/plant, leaf area index and cane diameter in both seasons, data in Table (2) show highly significant difference among sugarcane varieties for growth attributes. The Giza 9 variety produced the greatest values of all traits in the two seasons of study. This superiority can be mainly attributes to the increase in their number of tillers/plant and leaf area index and consequently increased photosynthesis by plant. These results are in agreement with those obtained by Nazir (2000) and Naqvi (2005).

Results recorded in Tables (3 and 4) revealed that cane length at four sampling dates, also, number of tillers/plant, number of internode/plant, leaf area index and cane diameter (cm) significantly increased by increasing the rate of nitrogen fertilizer (200 kg N/fed) in both growing seasons. The highest increases in these growth characters were obtained by application of 200 kg N/fed. However, the lowest values were recorded by using 120 kg N/fed. It is evident that each increase in the rate of nitrogen fertilizer from 120 to 200 kg N/fed was accompanied by highly significant increased in all growth characters. Similar results were found by Wiedenfeld (1995) and Thorburn et al. (2005).

Different dates of nutrients show significant effect of all growth attributes during both seasons. However, the application of Zn +Fe produced the highest all growth attributes in both seasons. The findings of Khan et al. (1997) and Tunio et al. (2004) are in contrast with these results they reported that of the most micronutrient exhibited a positive of all growth attributes.

Tables (3 and 4) indicated that growth characters of sugarcane plants significantly affected by the nitrogenous fertilizer and micronutrients, as well as, their interactions.

Concerning the interaction effect, data in Tables (3 and 4) indicated that Giza 9 variety and application of 200 kg N/fed produced the highest cane length, number of tillers/plant, number of internode/plant, leaf area index and cane diameter (cm) in both seasons.

The results reported inTables (3 and 4) indicated that the effective treatments for cane length of four sampling dates and number of tillers/plant, number of internode/plant, leaf area index and cane diameter were obtained from Giza 9 with foliar application of Zn +Fe treatment in both seasons.

Regarding the effect of interaction among sugarcane varieties, nitrogen fertilizer levels and micronutrients on all growth attributes characters in both seasons.

Table (2). Number of tillers/plant, Number of internode/plant, Leaf area index and Cane diameter as affectedby three varieties, nitrogen fertilizer and some micronutrients in 2014 and 2015 seasons.

Treatments	Number of tillers/plant		Number of internode/plant		Leaf area index		Cane diameter (cm)
Treatments	2014	2015	2014	2015	2014	2015	2014	2015
A)Varieties
Giza 9 Giza 47 Giza 49	4.76a 4.20b 3.46c	5.45a 4.43b 3.84c	20.30a 18.36b 16.24c	21.91a 20.39b 18.04c	8.53a 8.07b 7.25c	9.48a 8.97b 8.86c	2.47a 2.38b 2.26c	2.74a 2.64b 2.58c
LSD (0.05)	0.42	0.48	1.02	1.04	0.40	0.45	0.05	0.04
B)Nitrogen levels
120 160 200	3.64c 4.24b 4.74a	4.01c 4.70b 5.28a	16.10c 18.24b 20.57a	17.88c 20.28b 22.18a	7.73c 7.98b 8.21a	8.53c 8.87b 9.11a	2.26c 2.34b 2.47a	2.51c 2.62b 2.75a
LSD (0.05)	0.45	0.50	1.12	1.20	0.20	0.21	0.06	0.07
C)Micronutrient
Zn Fe Zn+Fe	3.68c 4.17b 4.67a	4.10c 4.60b 5.30a	15.71c 18.12b 21.06a	16.80c 20.14b 23.42a	7.13c 7.92b 8.88a	7.98c 8.88b 9.78a	2.21c 2.34b 2.60a	2.46c 2.61b 2.81a
LSD (0.05)	0.45	0.48	1.15	1.30	0.60	0.70	0.09	0.11
Interaction
AxB AxC BxC AxBxC	* * * *	* * * *	* * * *	* * * *	* * * *	* * * *	* * * *	* * * *

Means in the same column followed by the same letter are statistically equalled according to LSD (0.05) probability level.

*: Significant at (0.05) probability level

Table (3). Cane length (cm) as affected by three varieties, nitrogen fertilizer and some micronutrients in 2014 and 2015 seasons.

Treatments	2014				2015
Treatments	July	Aug.	Sept.	Oct.	July	Aug.	Sept.	Oct.
A)Varieties
Giza 9 Giza 47 Giza 49	179.97a 136.37c 147.79b	200.13a 151.16c 165.07b	223.35a 168.70c 183.82b	247.17a 186.86c 203.78b	180.39a 138.52c 149.23b	210.70a 173.35c 187.09b	222.91a 168.36c 183.31b	241.04a 187.08c 203.41b
LSD (0.05)	5.40	6.10	8.10	9.70	6.10	6.40	7.10	9.30
B)Nitrogen levels
120 160 200	140.24c 155.97b 169.31a	155.51c 175.03b 188.27a	173.08c 192.92b 209.41a	192.09c 214.17b 232.30a	141.15c 156.79b 170.29a	157.04c 173.40b 184.79a	173.39c 192.30b 208.10a	186.25c 214.17b 231.68a
LSD (0.05)	4.70	5.20	7.10	10.20	5.01	5.60	6.80	9.80
C)Micronutrient
Zn Fe Zn+Fe	142.95c 154.37b 166.32a	158.84c 172.57b 186.40a	176.46c 191.63b 206.43a	195.99c 213.12b 250.69a	143.63c 155.67b 169.38a	158.82c 171.28b 186.60a	176.82c 190.40b 206.88a	189.73c 211.82b 230.47a
LSD (0.05)	5.10	6.30	7.50	10.4	5.18	6.50	7.20	10.20
Interaction
AxB AxC BxC AxBxC	* * * ns	* * * ns	* * * ns	* * * ns	* * * ns	* * * ns	* * * ns	* * * ns

Means in the same column followed by the same letter are statistically equalled according to LSD (0.05) probability level.

*: Significant at (0.05) probability level

ns: not significant

Table (4). Interaction between three cultivars and N-levels on cane length (cm)at three sampling dates in 2014 and 2015 seasons.

Treatments

2014

2015

Varieties

N-levels KgN/fed

July

Aug.

Sept.

Oct.

July

Aug.

Sept.

Oct.

Giza 9

120

160

200

169.13

180.60

197.42

191.56

203.14

205.67

216.15

226.13

230.77

236.59

250.80

255.37

191.56

202.72

206.23

212.85

226.70

229.88

217.65

250.67

254.67

262.50

285.55

284.89

Giza 47

120

160

200

120.64

138.37

151.14

134.97

152.45

168.07

149.87

169.14

186.75

166.23

188.83

207.50

135.28

152.46

168.88

149.59

167.70

186.13

166.20

186.03

207.75

184.69

209.44

230.54

Giza 49

120

160

200

10.86

148.34

167.62

141.66

148.50

188.72

157.59

183.16

209.70

174.41

203.53

232.69

144.26

164.82

187.74

157.42

182.78

209.72

174.90

203.50

232.94

194.31

226.11

258.70

LSD (0.05)

5.50

6.30

8.30

10.50

6.30

6.50

7.60

10.10

B. Yield and Qualitative characters

Data inTables (5 and 6) showed that Giza 9 variety was significantly superior in yield and Qualitative characters i.e. cane girth, cane yield, Brix percentage of TSS%, sucrose %, purity % and commercial sugar (CCS%) than the other two sugarcane varieties Giza 47, Giza 49 varieties. Differences in these traits among sugarcane varieties under study may be due to differences in their genetic make and to response to environmental factors affecting development processe and ability to uptake the available nutrients. These results are in harmony with those obtained by Sharma et al. (2002) and Wilson and Leslie (1997).The obtained results given in Tables (5 and 6) showed, clearly, that nitrogen fertilizer levels exhibited significant effect on all estimated traits during the two cropping seasons of the study. Notably increasing nitrogen fertilizer level resulted in a significant increase in cane girth, cane yield (ton/ha), Birx percentage (TSS %), sucrose %, purity % and CCS%. These findings might be attributed to more adsorption of nutrition which reflect more growth substance more cell division and enlargement more tissues and organs and plant elongation. Also, the nitrogen fertilizer may increase the synthesis of endogenous phytohormones which cause the formation of big active root system which allow more nutrients uptake. The previous results agreed more or less with the findings obtained by Yadava (1991), Wiedenfeld (1995) and Pratop et al. (1996). Effect of Fe + Zn treatments on sugarcane are presented in Tables (5 and 6). Data cleared that application of all treatments caused marked increases in yield and qualitative characters. The highest values of cane girth, cane yield (ton/ha), Brix percentage (TSS %), sucrose %, Purity % and CCS % by foliar application of mixture Zn +Fe in both seasons. Similary, Dhanascharan and Bhuvaneswari (2004), noticed that Zinc and iron or in combination significantly increased Purity (%) of cane juice, sucrose (%) and Brix (TSS %). Similar results were obtained by Sharma et al. (2002) and Raskar and Bhai (2004).All first and second order interaction on yield and quality were significant in both seasons, Tables (5 and 6). Generally, Giza 9 variety with application of 200 kg N/fed and mixture of Zn +Fe treatment gave the best growth characters, yield and quality for sugarcane under Aswan conditions.

Table (5). Cane girth and cane yield (ton/ha) as affected by three varieties, nitrogen levels and micronutrients during 2014 and 2015 seasons.

Treatments	Cane girth (cm)		Cane yield (ton/ha)
Treatments	2014	2015	2014	2015
A)Varieties
Giza 9 Giza 47 Giza 49	2.35a 2.15b 2.09c	2.61a 2.39b 2.32c	163.32a 151.46b 137.15c	180.95a 167.74b 153.12c
LSD (0.05)	0.04	0.06	9.40	9.60
B)Nitrogen levels
120 160 200	2.12c 2.25b 2.35a	2.29c 2.44b 2.60a	141.54c 148.56b 165.97a	153.59c 165.96b 187.11a
LSD (0.05)	0.06	0.08	6.70	7.90
C)Micronutrient
Zn Fe Zn+Fe	2.10c 2.19b 2.32a	2.32c 2.42b 2.58a	138.22c 149.54b 164.84a	153.53c 166.12b 179.77a
LSD (0.05)	0.07	0.08	8.90	8.50
Interaction
AxB AxC BxC AxBxC	* * * *	* * * *	* * * *	* * * *

Means in the same column followed by the same letter are statistically equalled according to LSD (0.05) probability level.

*: Significant at (0.05) probability level

Table (6). Total soluble solids (TSS), Sucrose content and juice Purity (%) and Commercial cane sugar (CCS%) as affected by three varieties, nitrogen fertilizer and some micronutrients in 2014 and 2015 seasons.

Treatments	Brix (TSS %)		Sucrose (%)		Purity (%)		Commerical cane sugar (CCS %)
Treatments	2014	2015	2014	2015	2014	2015	2014	2015
A)Varieties
Giza 9 Giza 47 Giza 49	20.14a 18.13b 16.29c	22.39a 20.14b 18.12c	13.70a 13.44b 12.73c	15.15a 14.93b 14.23c	77.62a 60.56b 52.30c	86.61a 69.91b 58.13c	12.25a 11.89b 9.62c	13.56a 12.27b 10.75c
LSD (0.05)	1.02	1.10	0.50	0.45	7.10	9.50	0.50	0.60
B)Nitrogen levels
120 160 200	17.39c 18.36b 18.86a	19.33c 20.45b 20.98a	12.75c 13.37b 13.86a	14.17c 14.82b 15.33a	59.99c 62.30b 69.46a	66.26c 71.27b 76.27a	10.48c 10.95b 11.45a	11.59c 12.23b 12.77a
LSD (0.05)	0.45	0.48	0.47	0.45	6.10	5.50	0.45	0.48
C)Micronutrient
Zn Fe Zn+Fe	17.88c 18.20b 18.54a	19.85c 20.20b 20.60a	12.39c 13.23b 14.39a	13.77c 14.70b 15.90a	65.51c 63.91b 66.56a	66.47c 71.26b 76.40a	10.52c 10.96b 11.97a	11.13c 12.23b 13.39a
LSD (0.05)	ns	ns	0.70	0.80	ns	5.10	0.55	0.60
Interaction
AxB AxC BxC AxBxC	* ns ns *	* ns ns *	* * * *	* * * *	* * * *	* * * *	* * * *	* * * *

Means in the same column followed by the same letter are statistically equalled according to LSD (0.05) probability level.

*: Significant at (0.05) probability level

ns: not significant

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