Response of Two Maize Hybrids to Spatial Distribution and Nitrogenous Fertilization Rates

Gomaa, Mahmoud; Radwan, Fathy Ibrahim; Kandil, Essam Esmael; Emhemmed, Mohamed Abdallah

doi:10.21608/jalexu.2016.188229

Response of Two Maize Hybrids to Spatial Distribution and Nitrogenous Fertilization Rates

Journal of the Advances in Agricultural Researches

Article 8, Volume 21, Issue 2 - Serial Number 79, June 2016, Page 282-296 PDF (144.21 K)

Document Type: Research papers

DOI: 10.21608/jalexu.2016.188229

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Authors

Mahmoud Gomaa; Fathy Ibrahim Radwan; Essam Esmael Kandil; Mohamed Abdallah Emhemmed

Plant Production Department, Faculty of Agriculture (Saba Basha), Alexandria University, Alexandria, Egypt

Abstract

To investigate the response of two maize hybrids to spatial distribution and nitrogen fertilization rates. In this respect, two filed experiments were conducted at the Experimental Farm, Faculty of Agriculture (Saba Basha), Alexandria University during 2014 and 2015 seasons in a split- split plot design. Whereas, three factors can be illustrated as follows: the main plot included two maize hybrids (30N11 and 31G98), while, plant spacing (20, 30 and 40 cm) was arranged in the sub plots, while nitrogen fertilization (192, 288 and 384 kg N/ha.) allocated in sub- sub plot. The obtained results cleared that maize hybrid 30N11 recorded higher plant height (cm), ear weight (g), grain weight/ear (g), number of grains /ear, 1000-grains weight (g), number of rows/ear, grain yield (t/ha), biological yield (t/ha), harvest index (%), grains NPK and protein contents than the other hybrid 31G98 in the first and second seasons, respectively. The highest means values ofyield and chemical composition characters wereobtained using nitrogen fertilizer at rate of 384 kg/ha., in both seasons, while the lowestones were recorded by application of nitrogen at 192 kg/ha., in both seasons. Wider spacing between plants (40 cm) produced the higher yield and its components and protein content and NPK in the two successive seasons than narrower spacing (20 cm) which produced the lowest mean values of these characters.

Keywords

maize; hybrids; spatial distribution; nitrogen rates; yield; chemical composition

Full Text

INTRODUCTION

Maize (Zea mays L.) is the third most important staple food crop in terms of area and production after wheat and rice in Egypt. Also, in the world, it is one of the important cereal crops in the world after wheat and rice (Gerpacio and Pingali, 2007).

Improved cultural practices can play an important role in augmenting yield of corn crop. For an optimal yield, the nitrogen supply must be available according to the needs of the plant. On the other hand, suitable plants spacing for optimum leaf growth by controlling water, fertilizer and chemical inputs is essential for improving the growth variables responsible for high yield. Optimum plant densities ensure the plants to grow in their aerial and underground parts through different utilization of solar radiation and nutrients. When the plant density exceeds an optimum level, competition among plants for light above ground or for nutrients below the ground become severe, consequently the plant growth slows down and the grain yield decreases (Hasanuzzaman et al., 2009). Plant population is an improtant factor which affects the crop yield. Yield was increased by 4% with increasing plant density (Shapiro and Wortmann, 2006). Higher plant population produce 25% more grain yield and 38% more biomass as compared with low plant population and early sown crop produce 19% more grain yield and 11% more biomass than late planted crop (Abdul et al., 2007).

Maximum crop production can be achieved by development of improved crop hybrids and suitable growing environment and soil with optimum plant population/ha. Optimum plant population is the prerequisite for obtaining maximum yield (Trenton et al., 2006 and Gustavo et al., 2006).

Hybrids exhibited such variations in their yield attributes as cob length (cm), number of row/cob, number of kernels/row, number of kernels/cob, 100- kernel weight (g), stover yield Mg/ha., grain yield Mg/ha, biological yield ton/ha., and harvest index (%), and protein %. However, plant population 64000 plant/ha., gave the highest mean values for most studied characters and protein %. , and reduced weeds spread. Also, hybrid “TWC 352” recorded the highest values of most studied parameters under Alexandria conditions (Kandil, 2014).

Nitrogen is a key factor for plant photosynthesis, ecosystem productivity and leaf respiration (Johnson, 2001 and Martin et al., 2008). Nitrogen stress may affect the light use efficiency and consequently influence long-term changes in vegetation biomass and carbon sequestration (Peng et al., 2012). Increase nitrogen fertilization levels upto 200 kg ha^-1 enhanced the plant height, grain yield and straw yield of hybrid maize, whereas increasing nitrogen levels decreased the harvest, grain, and straw ratio (Dawadi and Sah, 2012). The lowest ear weight was related to the lowest nitrogen level, while the highest ear weight was observed by the highest nitrogen level (240 kg N ha^-1), while there was no significant difference among nitrogen levels was observed on harvest index (Hoshang, 2012). Nitrogen fertilization levels, maize hybrids and their interactions showed such significant effects on maize growth, crop yield and its components. The maximum plant height, leaf area index (LAI), chlorophyll SPAD unit, number of rows/cob , number of kernels/row, number of kernels cob, 1000 grain weight, stover, grain, biological yields, harvest index and protein content were produced by the application either 429 or 357 kg N/ha (Kandil, 2013). There were gradual and significant increases in all growth parameters and grain yield resulted from foliar spray by raising N- fertilizer upto 288 kg N/ha., in both seasons. The S.C Pioneer 30K09 maize hybrid treated with 288 N/ha., produced the maximum values of plant height and grain yield in both seasons (Faheed et al., 2016).

Keeping in view the importance of plant density and nitrogen fertilization, the study was conducted to find out optimum plant spacing and suitable nitrogen fertilization level for getting higher yield of maize hybrid.

MATERIALS AND METHODS

The present study was carried out at the Experimental Farm, Faculty of Agriculture (Saba- Basha), Alexandria University, Egypt, during the two successive growth summer seasons of 2014 and 2015, to study the response of two maize hybrids to spatial distribution and nitrogen fertilization rates in a split- split plot design. Whereas, three factors can be illustrated as follows: the main plot included two maize hybrids (30N11 and 31G98), while plant spacing (20, 30 and 40 cm) was arranged in the sub plots, while nitrogen fertilization (192, 288 and 384 kg N/ha.) allocated in sub- sub plot.

The grains of the tested two hybrids (31G98 and 30N11) were obtained from Maize Research Section Agriculture Research Center, Ministry of Agriculture. The grains were sown on May 8^th and 10^th 2014 and 2015 seasons, respectively.

Soil texture was clay loam. A surface sample (0-30 cm) was collected before planting to identify some physical and chemical properties of this soil, as shown inTable (1) according to Page et al. (1982) and Klute (1986). The preceding crop was Egyptian clover (berseem) in the first season and barley (Hordium vulgare, L.) in the second season, respectively.

Each sub sub plot size was 12.60 m² included 6 ridges each 3 m in length and 0.70 m in width with the distance between hills as the above treatments mentioned.

Phosphorus fertilizer was added at rate of 100 kg calcium super phosphate (15.5% P₂O₅) just before sowing. Mineral nitrogen fertilizer was fully given the dose in a form of urea (46% N) after thinning before the first irrigation and before the second irrigation.

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

Soil properties
	Season
	2014	2015
A) Mechanical analysis :
Clay % Sand % Silt %	38 32 30	37 33 30
Soil texture	Clay loam soil
B) Chemical properties
pH ( 1 : 1) E.C. (dS/m) (1:2)	8.20 3.80	8.31 3.70
1) Soluble cations (1:2) (cmol/kg soil)
K⁺ Ca⁺⁺ Mg⁺⁺ Na⁺⁺	1.52 9.4 18.3 13.50	1.54 8.7 18.5 13.8
2) Soluble anions (1 : 2) (cmol/kg soil)
CO₃^--+ HCO₃^- Cl^- SO₄^— Calcium carbonate (%) Total nitrogen % Available phosphate (mg/kg) Organic matter (%)	2.90 20.4 12.50 6.50 1.00 3.70 1.41	2.80 19.80 12.60 7.00 0.91 3.55 1.40

Grain yield and yield components as cob length (cm), number of rows cob^-1, number of kernels row^-1, number of kernels cob^-1,100- kernel weight (g), stover yield ton ha^-1, grain yield ton ha^-1, biological yield (ton ha^-1) harvest index (H.I.%) are measurements were obtained as an average of 2 ridges from mid of each plot.

Protein percentage was determined by estimating the total nitrogen in the grains and multiplied by 6.25 to obtain the percentage according of grains protein percentage to A.O. A.C. (1990). NPK percentages were determined in the dry grains. Their dry weights were determined following drying in a drying chamber to a constant weight at 75^oC for 72 hour according to Tandon (1995). After dryness, the plant samples were milled and stored for analysis as reported. However, 0.5 g of the grains powder was wet-digested with H₂SO₄–H₂O₂ mixture according to (Lowther, 1980) and the following determinations were carried out in the digested solution to determine NPK. Total nitrogen was determined in digested plant material colorimetrically by Nessler`s method (Chapman and Pratt, 1978). Phosphorus was determined by the Vanadomolyate yellow method as given by Jackson (1973) and the intensity of colour developed was read in spectrophotometer at 405 nm. Potassium was determined according to the method described by method Jackson (1973) using Beckman Flame photometer.

Data obtained was exposed to the proper method of statistical analysis of variance as described by Gomez and Gomez (1984). The treatments means were compared using the least significant differences (L.S.D.) test at 5% level probability by using the split- split model as obtained by CoStat 6.311(2005) as statistical program.

RESULTS AND DISCUSSIONS

Results recorded in Tables (2 and 3) revealed that plant height (cm), ear weight (g), grain weight/ear (g), number of grains/ear, 100-grains weight (g), number of rows/ear, grain yield (t/ha), biological yield (ton/ha) and harvest index (%) of two maize hybrids were, significantly, affected by plant spacing and nitrogen fertilizer rates in both seasons.

Results presented in the same tables demonstrated that maize hybrid “30N11” had higher value for the yield and its components i.e. plant height (cm), ear weight (g), grain weight/ear (g), number of grains /ear, 100- grains weight (g), number of rows/ear, grain yield (t/ha), biological yield (ton/ha) and harvest index (%) than the other hybrid “31G98” in the first and second seasons, respectively. The difference may be attributed to genetically differences between two maize hybrids which play an important role for make up the available nutrients and yield for the maize hybrids. These findings are in harmony with those obtained by Kandil (2014).

Results, also demonstrated that spacing between hills (40 cm), significantly, increased the yield and its components than narrower spacing (20 cm). These results are in agreement with those reported by Ahmad et al. (2010), Saadat et al. (2010), Peykarestan and Seif (2012), Moosavi et al. (2012), Lyocks et al. (2013) and Kandil (2014) who showed that there was a significant difference among plants spacing on maize characters.

On the other side, results presented in Tables (2 and 3) revealed that increasing nitrogen fertilizer level up to 384 kg/ha., significantly, increased plant height (cm), and yield components of maize i.e. ear weight (g), grain weight/ear (g), number of grains /ear, 100- grains weight (g), number of rows/ear, grain yield (t/ha), biological yield (t/ha) and harvest index (%) than application of 192 kg N/ha. It can be noticed generally that grain yield and its components affected by nitrogen fertilizer which play an important role in plant growth and finally appeard in gigher grain yield for two hybrids of maize. These finding were consistent with those obtained by Kumar(2008), Khan et al. (2012), Moraditochaec et al. (2012), Nemati and Sharifi (2012) and Kandil (2013).

The interaction between maize hybrids and plant and plant spacing reveal that the highest mean values of straw, and biological yield and harvest index were obtained with 30N11 hybrid at 40 cm. In the contrast, growing 31G98 at 20 cm produced the lowest ones during two cropping seasons (Table 4).

With regard to maize hybrids x nitrogen level interaction, results in Table (5) showed that the maize hybrid “30N11hybrid” with 288 kg N/ha., recoded the highest mean value of grain yield in the second season.

Considering interaction among maize hybrids x spacing x nitrogen fertilization level were significant for yield and its components characters in both seasons as cleared in Table (6). However, results revealed that wider spacing of “30N11” hybrid plants at (40 cm) and fertilized with 384 kg N/ha., produced the highest mean value of grain and straw and biological yield in the two respective seasons.

Table (2). Plant height, yield and its components as affected by two maize hybrids, plant spacing and nitrogen

Treatments

Plant height (cm)

Ear weight (g)

Grain weight/ear (g)

Number of grains /ear

100-grain weight (g)

Season

2014

2015

2014

2015

2014

2015

2014

2015

2014

2015

Maize hybrids (H)

31G98

30N11

LSD at 0.05

210.59b

217.33a

0.84

211.30b

219.18a

1.50

225.12b

286.07a

26.13

224.43b

293.90a

0.61

170.86b

223.88a

0.65

172.91b

227.32a

1.62

511.81b

556.07a

2.29

518.11b

564.44a

5.38

39.79b

47.09a

0.20

40.37b

47.56a

0.25

Plant spacing (cm): (S)

LSD at 0.05

209.11c

214.66b

218.11a

1.85

210.40c

216.40b

218.94a

1.28

225.91c

249.36b

291.51a

13.53

222.57c

254.63b

300.29a

0.75

166.54c

189.63b

235.94a

2.10

168.35c

192.44b

239.55a

0.72

507.33c

526.55b

567.94a

4.21

515.94c

532.72b

575.16a

3.99

40.55c

43.97b

45.81a

0.21

40.94c

44.63b

46.33a

0.20

N- fertilizer levels (kg/ha.)

288

384

LSD at 0.05

209.88c

211.94b

220.05a

1.49

207.78c

215.92b

222.03a

1.20

222.49c

258.66b

285.64a

18.87

214.39c

267.46b

295.64a

0.64

163.83c

196.37b

231.92a

2.00

165.69c

198.67b

235.99a

0.74

446.27c

524.33b

631.22a

3.71

451.16c

533.83b

638.83a

3.71

40.46c

43.43b

46.45a

0.64

41.02c

43.96b

46.91a

0.24

Interaction

H x S

H x N

S x N

H x S x N

fertilizer rates in 2014 and 2015 seasons.

Means at the same column followed by the same letter are significantly different according to L.S.D. at 0.05 value, ns: not significant and *: significant difference at 0.05 level of probability.

Table (3). Yield and its components as affected by two maize hybrids, plant spacing and nitrogen fertilizer rates in 2014 and 2015 seasons.

Treatment

Number of rows/ear

Straw yield (ton/ha)

Grain yield (ton/ha)

Biological yield (ton/ha)

Harvest index

(%)

2014

2015

2014

2015

2014

2015

2014

2015

2014

2015

Maize hybrids (H)

31G98

30N11

LSD at 0.05

13.47b

14.41a

0.45

13.70b

14.58a

0.11

9.46b

11.43a

0.745

9.49b

11.47a

0.633

6.39 b

7.69 a

0.395

7.08b

8.32a

0.609

15.86b

19.12a

1.14

16.57b

19.80a

1.24

40.20a

40.12a

0.306

42.62a

42.00b

0.586

Plant spacing (cm): (S)

LSD at 0.05

13.24c

14.04b

14.54a

0.07

13.53c

14.19b

14.70a

0.07

9.11c

10.65b

11.58a

0.503

9.04c

10.67b

11.73a

0.426

6.37 c

7.08 b

7.67 a

0.384

6.91c

7.71b

8.48a

0.405

15.48c

17.74b

19.25a

0.697

15.95c

18.39b

20.21a

0.785

41.16a

39.67a

39.65a

1.57

43.26a

41.90b

41.77b

0.806

N- fertilizer levels (kg/ha.)

288

384

LSD at 0.05

13.21c

13.96b

14.46a

0.09

13.45c

14.24b

14.73a

0.10

9.66b

10.59a

11.10a

0.551

9.71b

10.67a

11.06a

0.541

6.17b

7.41a

7.55a

0.541

6.86c

7.78b

8.47a

0.448

15.83b

17.99a

18.65a

0.962

16.57c

18.46b

19.52a

0.909

38.81b

41.15a

40.51a

1.60

41.27b

42.15b

43.52a

1.11

Interaction

H x S

H x N

S x N

H x S x N

n.s.

Means at the same column followed by the same letter are statistically significantly different to L.S.D. at 0.05 value, ns: not significant and *: significant difference at 0.05 level of probability.

Table (4). Interactions between maize hybrids and plant spacing for grain yield (ton/ha.), straw yield and biological yield and H.I % in 2014 and 2015 seasons.

Hybrid	Plant spacing	Grain yield (ton/ha)	Straw yield (ton/ha)		Biological yield (ton/ha)		Harvest index (H.I %)
		Season
		2015	2014	2015	2014	2015	2014	2015
31G98	20 30 40	6.16 6.89 8.20	7.45 9.66 11.28	7.47 9.51 11.50	13.28 15.98 18.31	13.63 16.40 19.70	43.32 39.12 38.15	44.70 41.64 41.52
30N11	20 30 40	7.66 8.54 8.77	10.77 11.64 11.88	10.61 11.84 11.97	17.69 19.49 20.18	18.28 20.38 20.73	38.99 40.21 41.16	41.82 41.91 42.28
LSD at 0.05		0.573	0.711	0.602	0.986	1.11	2.22	1.14

Table (5). Interactions between maize hybrids and nitrogen fertilizer levels for grain yield (ton/ha) and H.I % in 2014 and 2015 seasons.

Hybrid	N levels(Kg/ha.)	Grain yield (t/ha)	Harvest index (%)
		Season
		2015	2014	2015
31G98	192 288 384	5.95 6.95 8.35	38.11 40.82 41.66	40.71 41.91 45.24
30N11	192 288 384	7.77 8.62 8.59	39.52 41.49 39.36	41.82 42.39 41.80
LSD at 0.05		0.634	2.26	1.56

Table (6). Interactions among maize hybrids,plant spacing, and nitrogen fertilizer levels for grain yield (t/ha), biological yield and harvest index (HI %) in 2014 and 2015 seasons.

Hybrids

Plant spacing

N levels (kg/ha.)

Grain yield (ton/ha)

Biological yield (ton/ha)

Harvest index (H.I. %)

Season

2014

2015

2014

2015

2014

2015

31G98

192

288

384

4.12

5.92

7.44

4.56

5.88

8.04

10.38

13.46

16.00

11.12

13.24

16.52

39.69

43.76

46.50

41.03

44.40

48.67

192

288

384

4.66

6.16

8.16

5.50

6.16

9.00

13.11

16.28

18.56

13.83

15.76

19.60

35.51

37.74

44.10

39.75

39.11

46.05

192

288

384

6.96

8.13

6.00

7.80

8.80

8.00

17.76

19.85

17.33

18.84

20.84

19.41

39.12

40.95

34.39

41.35

42.22

40.99

30N11

192

288

384

6.14

7.52

7.10

6.70

8.36

7.94

16.09

18.28

18.70

16.46

19.36

19.02

38.04

40.98

37.96

40.99

43.05

41.77

192

288

384

7.64

8.48

7.42

8.25

9.12

8.26

18.88

20.60

19.00

19.57

21.48

20.08

40.46

41.17

39.01

42.16

42.46

41.10

192

288

384

7.52

8.24

9.16

8.36

9.58

18.77

19.48

22.29

19.61

20.07

22.52

40.05

42.32

41.11

42.64

41.65

42.54

LSD at 0.05

1.32

1.09

2.36

2.23

3.92

2.71

Results recorded in Table (7) revealed that percentage of nitrogen, phosphorus, potassium and protein in maize grains were, significantly, influenced by adding high level of nitrogen.

Maize hybrid 30N11 recorded higher grains NPK and protein content than the other hybrid 31G98 in the first and second seasons, respectively.these results can be concluded that the ability to transport enough absorbed nitrogen, phosphorus, and potassium percentages in grains plant. These results agreed with those obtained by Amin et al. (2003) and Atia and Abdel- Azeem (2005).

The highest values of all chemical compositions character were obtained using nitrogen fertilizer at rate 384 kg/ha., in both seasons, while, the lowest ones was recorded by application nitrogen at 192 kg/ha., as shown in (Table 7) in both seasons. These results indicate that N- fertilization rate increased the capacity of plant in absorbing nutrients. These results are in agreement with others results were reported by Martin et al. (2008), El- Gizawy and Salem (2010) and Dawadi and Sah (2012).

Results in Table (7) revealed that wider spacing between plants (40 cm) produced higher protein content and NPK in the two successive seasons than narrower spacing (20 cm) that produced the lowest mean values of these characters.

On the other side, increasing nitrogen fertilizer from 192 to 384 kg N/ha., significantly, increased grain NPK and protein contents in 2014 and 2015 seasonsas shown in Table (7). These results are in agreement with those obtained by Sahoo and Mahapatra (2004), Oktem and Oktem (2005), Kar et al. (2006), Melkonian et al. (2008), El-Gizawy and Salem (2010) and Tang et al. (2015).

Table (7). Macronutrients (N, P and K) and protein percentages as affected by maize hybrids, plant spacing and nitrogen fertilizer rates in 2014 and 2015 seasons.

Treatment

N (%)

P (%)

K (%)

Protein (%)

Season

2014

2015

2014

2015

2014

2015

2014

2015

Maize hybrids (H)

31G98

30N11

LSD at 0.05

1.27b

1.32a

0.01

1.34b

1.36a

0.01

0.634b

0.713a

0.003

0.638b

0.720a

0.003

1. 67b

1. 86a

0.01

1.68b

1.90a

0.05

7.79b

8.28a

0.07

8.37b

8.51a

0.11

Plant spacing (cm): (S)

LSD at 0.05

1.22c

1.31b

1.36a

0. 02

1.28c

1.36b

1.40a

0. 01

0.648c

0.673b

0.699a

0. 002

0.652c

0.681b

0.704a

0.003

1.60c

1.74b

1.95a

0. 02

1.61c

1.76b

1.99a

0. 02

7.65c

8.22b

8.51a

0. 13

8.03c

8.52b

8.78a

0. 07

N- fertilizer levels (kg/ha.)

288

384

LSD at 0.05

1.21c

1.30b

1.38a

0.01

1.25c

1.35b

1.44a

0.01

0.545c

0.682b

0.793a

0.001

0.551c

0.685b

0.800a

0.001

1.57c

1.76b

1.96a

0. 01

1.58c

1.80b

1.99a

0. 02

7.57c

8.14b

8.67a

0.09

7.82c

8.46b

9.04a

0.09

Interaction

H x S

H x N

S x N

H x S x N

Means at the same column followed by the same letter are statistically equaled according to L.S.D. at 0.05 value, ns: not significant and *: significant difference at 0.05 level of probability.

CONCLUSIONS

Considering the obtained results, it can be concluded that application of 384 kg N ha^-1 and with wider spacing (40 cm) between plants to the maize hybrid ‘30N11’ is an optimal for obtaining higher grain yield of maize under the agro-metrological conditions of Alexandria, Egypt.

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