CONTACT : BISHNU HARI ADHIKARY        adhikary_bishnu@yahoo.com 
 

85 

Abstract 
Grain yield production of maize is greatly affected by varieties and fertilizer 
levels. This study was conducted to determine the effects of different rates 
of fertilizers (nitrogen, phosphorus, potassium fertilizers and farmyard 
manures) on grain yield and yield attributing traits of different maize varieties 
during winter seasons of 2009/10 and 2010/011 at the research farm of 
National Maize Research Program, Rampur, Chitwan, Nepal. Six levels of 
fertilizers [Control (Zero fertilizer), FYM @ 10 t/ha, FYM@ 10 t/ha plus 60:30 
20 kg NPK/ha, FYM@ 10 t/ha plus 120: 60: 40 kg NPK/ha, FYM@ 10 t/ha plus 
180: 90: 60 kg NPK/ha, and 120: 60: 40 kg NPK/ha] and four maize varieties 
(Rampur Composite, Manakamana-4, Across9942 × Across 9944 and 
S99TLYQ-B) were evaluated in randomized complete block design with three 
replications. The results showed that grain yield was non-significant for maize 
genotypes but the fertilizers levels were highly significant for grain yield. 
Rampur Composite produced the highest grain yield (5195 kg/ha), followed 
by Manakamana-4 (5074 kg/ha), Across9942 × Across9944 (5052 kg/ha) and 
S99TLYQ-B (4789 kg/ha) with the application of NPK 180: 90: 60 kg/ha plus 
FYM 10 t/ha. This information is useful in generating suitable fertilization 
packages for obtaining higher grain yield of maize varieties. 

ISSN : 2580-2410 
eISSN : 2580-2119 

 
 

 

Productivity of winter maize as affected by varieties and  
fertilizer levels 
 
Bishnu Hari Adhikary, Bandhu Raj Baral,  & Jiban Shrestha 
 
National Maize Research Program, Rampur, Chitwan, Nepal.  
 

 
 
  
  
 
 
 
 
 
 
 
 
 
 
Introduction 

Maize (Zea mays L.) has the highest productivity per unit area as compared to other 
cereal crops. It ranked third among the cereal crops in the world after wheat and rice. In 
Nepal, it is the second most important staple food crop in terms of both area and production 
after rice but it is the first staple crop for hills.   In Nepal, maize has been grown over an area 
of 954158 hectares in 2017/18 with a production of 2555847 tons and a productivity of 2.67 
t/ha (MoALD, 2018). The production of maize is low as compared to other countries.  

The production can be improved or increased through adequate nutrient 
management practices. Maize being the heavy feeder crop, a balanced dose of organic and 
inorganic  application  of  fertilizer  is  needed  for  increased  productivity. Fertilizer 
management is crucial for maize cultivation (Baral et al., 2015). Manures and fertilizers both 
play an important role in maize cultivation. N is usually applied in 3 equal splits at sowing, 
knee-high stage and tasseling stage. als/ha of grain yields and likewise, it can be reduced or 

        OPEN ACCESS             International Journal of Applied Biology 

Keyword 
Fertilizer and manures, 
Maize genotypes,  
Grain yield, 
Yield attributing traits. 

Article History 
Received 30 March 2020 
Accepted 15 June 2020 

International Journal of Applied Biology is licensed under a 
Creative Commons Attribution 4.0 International License, 
which permits unrestricted use, distribution, and reproduction 
in any medium, provided the original work is properly cited.  

 



International Journal of Applied Biology, 4(1), 2020 

 86 

increased as per its expected yield. Phosphorus (P) is the next most important plant nutrient 
after N which is found difficult in most soils. It has a beneficial effect on root growth and plant 
health. This nutrient should be applied initially at the early stage because of its low solubility 
in water. It should be applied in a moist zone to be transformed quickly for early absorption 
by the plant. The dose of P should be balanced with the dose of N applied. Potassium is 
considered to be the 3rd most essential fertilizer element, it is not found deficient in most of 
the soils. It is essential for the vigorous growth of the plant and for so many other metabolic 
activities.K application through fertilizers has been responding satisfactorily (Regmi et al., 
2002). Maize being a high nutrient mining crop it needs a higher amount of NPK for its 
economic production. Farmers applying 20-25 t/ha of compost/FYM (manures) are not 
sufficient to replenish the harvested nutrients and hence need a sufficient amount of mineral 
fertilizer addition with heavy manure application (Joshy, 1997). Adhikary et 
al. (2001) reported that the highest maize grain yield (4.65 t/ha) could be obtained when the 
crop is fertilized by 20 t of compost plus 100: 75: 40 kg/ha of N, P2O5, and K2O in the acidic 
soils of Malepatan, Pokhara.  Adhikary and Ranabhat (Adhikary and Ranabhat, 2004) studied 
the economics of manure and fertilizer application on maize production and concluded that 
most economic dose of fertilizer was 100: 75: 40 kg N, P2O5 and K2O/ha from inorganic 
sources and  20 t/ha of compost that contained 280   kg N, 184 kg P2O5 and 216 kg K2O. 
Adhikary et al. (2007)  studied the effect of fertilizer and agricultural lime on grain yield of 
different maize genotypes in the Western hills of Nepal and reported that improved maize 
variety (Manakamana-1) did not differ in grain production with the local variety when 
supplied with fertilizers at 60: 30: 30 kg N, P2O5 and K2O and 4 t/ha of agri-lime. Adhikary 
(2008) also studied the effects of nitrogen on maize inbred (NML-1) and reported that 
increased seed yield (2.85 t/ha) was obtained with this variety when supplied with 180 kg N 
and crop planted at the density of 66,666 plants/ha and crop fertilized along with the 
recommended dose of P and K fertilizers. Series of experiments were conducted to evaluate 
the effects of fertilizers on different maize genotypes during the years 2009 and 2010. The 
results revealed that the highest grain yield of 6.28 t/ha was produced by the S99TLYQ-B 
when the crop was fertilized with 120: 60: 40 kg N, P2O5 and K2O/ha and 10 t/ha of compost 
(NARC, 2010). Hence,   balanced dose of fertilizers is needed to increase the crop yield of 
maize in acid soils. The number of fertilizers to be applied in maize depends largely on the 
genotypic makeup of plants. 

The objective of these experiments were to study the response of fertilizer nutrients 
at different levels on the different maize genotypes in the soil condition of Rampur, Chitwan, 
Nepal. 

 
Materials and Methods 
Experimental site 

The site was located in central Nepal at 27° 40’ N latitude and 84° 19’ E longitude with 
an elevation of 228 m above mean sea level and had a subtropical climate (NMRP, 2011). 
Maize was planted on sandy silt loam, acidic soil (pH 5.54). Fertilizer was applied in the form 
of Urea, di-ammonium phosphate (DAP), and murate of potash (MoP). Entire dose of DAP and 
MoP were applied at the time of sowing while half of the urea was first top-dressed at the 
knee-high stage and second top-dressed at tasseling stage. The average data derived from 
both years on maximum temperature ranged from 21.95 (January) to 36.35 0C (April), the 
minimum temperature varied from 9.4 (January) to 24.65 0C (October). There is no rainfall in 



International Journal of Applied Biology, 4(1), 2020 

 87 

November and January, minimum rainfall (1.1 mm) occurred in January and maximum rainfall 
occurred in 99.35 mm (April). Similarly, average data on relative humidity showed that 
minimum humidity (76.8%) occurred in April and maximum relative humidity (99%) occurred 
in December. The details of weather data of individual year were shown in Table 2. 

 
Table 1. Monthly mean weather condition during crop growing season (October-April) in 
2009/10 and 2010/11 winter seasons at Rampur, Chitwan, Nepal 

Month Maximum 

temperature (0C) 

Minimum 

temperature (0C) 

Rainfall (mm) Relative humidity 

(%) 

 2009/10 2010/11 2009/10 2010/11 2009/10 2010/11 2009/10 2010/11 

October  31.4 31.4 26.5 22.8 101 48.6 97.0 97.5 

November 27.1 27.1 21.6 17.0 0.0 0.0 99.0 98.8 

December 24.0 24.0 16.0 9.1 2.2 0.0 99.0 99.0 

January  20.0 23.9 10.3 8.5 0.0 0.0 94.6 100.5 

February 25.4 26.1 11.9 15.1 0.0 34.9 89.5 96.3 

March 33.1 31.1 19.1 18.9 0.0 34.4 82.2 83.2 

April 38.1 34.6 23.3 19.6 165 33.7 75.4 78.2 

*Source: (NMRP, 2011)  
 

Experimental design, treatments and crop management 
This experiment was conducted at the farm of National Maize Research Program, 

Rampur, Chitwan, Nepal during the winter season of the year 2009/10 and 2010/11.The crop 
was planted in October and harvested in April. Twenty four treatment combinations 
consisting of six levels of fertilization and four maize genotypes were replicated three times 
and laid out in a randomized complete block design. The details of the treatment 
combinations are given in the following Table 1.  Row to row spacing 75 × 25 cm was 
maintained. The net harvested area was 7.2 m2. The gross plot size was 12 m2. 
 
Table 2. The details of the treatments used in experiment in 2009/10 and 2010/11 winter 
seasons at Rampur, Chitwan, Nepal 
Genotypes Fertilizer rates 

V1= Rampur Composite F1=Control (Zero fertilizer) 

V2= Manakamana-4 F2= FYM @ 10 t/ha 

V3=Across9942 × Across9944 F3= FYM@ 10 t/ha plus 60:30 20 kg NPK/ha 

V4= S99TLYQ-B F4=FYM@ 10 t/ha plus 120: 60: 40 kg NPK/ha 



International Journal of Applied Biology, 4(1), 2020 

 88 

 F5=FYM@ 10 t/ha plus 180: 90: 60 kg NPK/ha 

 F6= 120: 60: 40 kg NPK/ha 

 
Data recorded 

Observations were taken on plant height, ear height, cob length, no. of Kernel rows 
per cob, no. of kernels per rows, and grain yield. Plant height and ear height were recorded 
at just near to harvesting and the rest of the data were recorded after harvesting. At maturity, 
central two rows from each the plot were separately harvested and the fresh ear weight was 
measured in each plot. Grain yield (kg/ha) at 15% moisture content was calculated using fresh 
ear weight with the help of the below formula given by Carangal et al. (1971), Shrestha et al. 
(2019) and Upreti et al. (2020). 

 
Where, 

FWT : Fresh weight of ear in kg per plot at harvest 

HMP : Grain moisture percentage at harvest 

DMP : Desired moisture percentage, i.e. 15% 

NPA : Net harvest plot area, m2 

SCF : Shelling coefficient, i.e. 0.8 
 

Statistical analysis 
Data were statistically analyzed. Analysis of variance for all data was analyzed using 

the MSTAT computer program. The significant differences between genotypes were 
determined using the least significant difference (LSD) test at 1% or 5% level of significance 
(Gomez and Gomez 1984; Shrestha, 2019). 

 

Results and Discussion  
The interaction between different fertilizer levels and varieties on grain yield showed 

that the highest grain yield (5195 kg/ha) was obtained in Rampur Composite followed by 
Manakamana-4 (5074 kg/ha) and Across9942 × Across9944 (5052 kg/ha) under treatment of 
application of NPK 180: 90: 60 kg/ha plus FYM 10 t/ha. Similarly, S99TLYQ-B produced the 
highest grain yield (4789 kg/ha) under the same level of fertilization (Figure 1). 



International Journal of Applied Biology, 4(1), 2020 

 89 

 
Figure 1. Schematic diagram for interaction effect between maize genotypes and  

fertilizer levels. 
 
The increasing amount of nitrogen and phosphorus fertilizer application increased 

yield attributing traits in maize. The highest yield attributing traits namely cob length, no. of 
kernel rows per cob and no. of kernels per kernel rows were found under the level of 
fertilization (180:90:60 kg NPK plus 10 t FYM/ha) in Rampur Composite, Manakamana-4, 
Across9942 × Across9944. Gokmen et al. (2001) and Wajid et al. (2007) reported that 1000 
grain weight increased with increasing N levels. Gungula et al. (2007) and Dawadi (2009) 
observed a number of kernels/ear and number kernel rows/cob increased with increasing 
nitrogen levels. The increase in 1000-grain weight with increasing P levels might be due to 
improvement in the source-sink relationship. These results are supported by the findings of 
Ahmad (1989) and Toor (1990). 
 
Table 3. Effect of different level of manures and fertilizers on different maize genotypes in 
2009/10 and 2010/11 winter seasons at Rampur, Chitwan, Nepal 

Treatme

nts 

Cob length 

(cm) 

Kernel rows per 

cob (No.) 

Kernel per kernel 

row (No.) 

Grain yield 

(kg/ha) 

2009/10  2010/11 2009/10 2010/11 2009/10 2010/11 2009/

10 

2010/

11 

V1F1 11.4 9.66 10.7 10.4 22.6 14.86 2860 1443 

V1F2 12.2 11.6 12 11.93 24.2 17.53 3740 2180 

V1F3 13.8 14.13 12.8 13.6 31.1 28.33 4960 2927 

V1F4 14.1 14.46 13 13.86 30.5 30.4 5840 3863 

V1F5 14.2 15.13 13.1 14 31.9 30.8 6260 4130 

V1F6 13.8 13.86 12.6 13.73 29.1 29.46 5630 3733 

V2F1 10.4 9.06 11.5 10 21.1 15.53 2240 1677 

V2F2 11.7 11.6 13.3 11.7 25.3 21.86 3830 2010 

V2F3 13.8 14.6 15.2 13.4 28.5 30.2 5340 3333 

V2F4 14.3 14.73 15.3 13.86 30.2 31 5960 3837 

F6F5F4F3F2F1

5000

4000

3000

2000

V4V3V2V1

5000

4000

3000

2000

Variety

V3

V4

V1

V2

Fertilizers

F3

F4

F5

F6

F1

F2



International Journal of Applied Biology, 4(1), 2020 

 90 

V2F5 14.9 14.86 15.5 14.26 31.7 31.73 5990 4157 

V2F6 14.2 13 15.1 12.93 30.7 27.2 5280 3240 

V3F1 9.7 8.33 11.7 9.2 19.7 13.8 2300 1163 

V3F2 11.6 10.8 13.7 11.53 25.5 21.13 3360 1953 

V3F3 12.6 13.2 15.7 12.03 29.3 30.4 5120 3033 

V3F4 13.3 13.66 15.7 13.33 28.8 29 6190 3630 

V3F5 13.4 13.93 16.3 13.43 30.9 29.53 6280 3823 

V3F6 13.2 13.2 15.1 13.16 29.1 28.23 5770 3290 

V4F1 9.9 7.2 11.6 9.33 20.7 12.66 2750 1460 

V4F2 11.7 10.2 13.5 10.13 25 20.06 3920 2083 

V4F3 14.3 13.53 14.9 12.26 28.3 25.4 4990 2890 

V4F4 14.9 13.73 15.2 12.13 32.5 29.73 5740 3380 

V4F5 13.9 13.13 14.9 12.53 30.5 26.06 5760 3817 

V4F6 14.1 13.4 14.9 12.03 29.1 28.6 5280 3140 

Mean 13 12.54 13.9 12.28 27.8 25.14 4810 2925 

CV(%) 4.62 9.36 7.52 7.99 6.25 14.63 15.32 17.44 

F-test 

(V) 

** ** ** ** Ns Ns Ns Ns 

(F) ** ** ** ** ** ** ** ** 

(V × F) Ns Ns Ns Ns Ns Ns Ns Ns 

LSD 

(0.05) 

0.402 0.788 0.701 0.658 1.428 2.468 605 419 

**Highly significant at 0.01 level, *Significant at 0.05 level and Ns: non-significant. 
 

In 2009/10 and 2010/11, the effect of genotypes was observed to be non-significant 
whereas the effect of fertilizers was found to be highly significant. The increasing amount of 
fertilizer up to 180 N kg/ha, phosphorus 90 kg/ha, and potassium 60 kg/ha increased the grain 
yield in both years.  Singh et al. (2000) indicated that grain increased with the increase in 
nitrogen level from 0-200 kg/ha. Khan et al. (2014) found an increasing amount of phosphorus 
increased the grain yield of maize at a constant level of 150 N kg/ha application; the maximum 
grain yield (5356 kg/ha) was recorded in Jalal variety when it was fertilized with 150:100 N:P 
kg/ha. In 2009/10 the highest grain yield (6068 kg/ha) was obtained at the highest level of 
fertilization (180:90:60 NPK kg/ha plus FYM 10 t/ha). The variety Rampur composite produced 
highest grain yield (4882 kg/ha) followed by Across9942 × Across 9944 (4837 kg/ha) and 
Manakamana-4 (4773 kg/ha) Similarly in 2010/11, grain yield was increased with an increased 
level of fertilization. The highest grain yield (3873 kg/ha) was obtained at the highest level of 
fertilization (180:90:60 NPK kg/ha plus FYM 10 t/ha). The variety Rampur composite produced 
highest grain yield (3046 kg/ha) followed by Manakamana-4 (3042 kg/ha) and Across9942 × 
Across 9944 (2816 kg/ha) (Table 4). 
 
 
 
 



International Journal of Applied Biology, 4(1), 2020 

 91 

Table 4. Grain yield under different fertilizer levels and genotypes in 2009/10 and 2010/11   
winter seasons at Rampur, Chitwan, Nepal               

Treatments        Grain yield (kg/ha) 

Fertilizer  levels 2009/10 2010/11 

F1 (Control) 2538 1436 

F2 (FYM 10 t /ha) 3713 2057 

F3 (60:30:20 NPK plus FYM 10t/ha) 5103 3046 

F4 (120:60:40 NPK plus FYM 10t/ha) 5938 3787 

F5 (180:90:60 NPK kg/ha plus FYM 10 

t/ha) 

6068 3873 

F6 (120:60:40 NPK kg/ha) 5490 3351 

CV(%) 15.32 17.4 

F-test ** ** 

LSD (0.05) 221.5 419.1 

Genotypes   

V1 (Rampur Composite) 4882 3046 

V2 (Manakamana-4) 4773 3042 

V3 (Across9942 × Across9944) 4837 2816 

V4 (S99TLYQ-B) 4740 
 

2795 

CV(%) 15.32 17.4 

F-test Ns Ns 

LSD (0.05) 605 342.2 

**Highly significant at 0.01 level, *Significant at 0.05 level and ns, non-significant. 
 

Conclusions 
The study showed that maize genotypes namely Rampur Composite, Manakamana-4, 

Across9942 × Across 9944 and S99TLYQ-B produced higher grain yield of 5195, 5074, 5052 
and 4789 kg/ha respectively with the application of NPK @ 180: 90: 60 kg/ha plus FYM 10 
t/ha. Similarly, produced the highest grain yield (kg/ha). The yield attributing traits namely 
cob length, no. of kernel rows per cob and no. of kernels per kernel rows were found  higher 
at the fertilization rate of 180: 90: 60 kg NPK/ha plus FYM 10 t/ha so such fertilization rate is 
suitable for maize varieties at Rampur, Chitwan, Nepal during winter seasons. 
 
Acknowledgements 

The authors would also like to thank National Maize Research Program Rampur 
(NMRP), Rampur, Chitwan, Nepal for the provision of research materials financial supports 
for conducting this research. 

 
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