CONTACT : GOPAL SAHA        saha.18@gmail.com 
 

68 

Abstract 
The low productivity of Aus rice in the tidal ecosystem of Bangladesh is mainly 
due to the difficulties in nitrogen (N) management under high tidal water along 
with unavailability of irrigation water during the onset of rice cultivation. Our 
present study demonstrated how the productivity of Aus rice could be improved 
using appropriate seedling raising methods and N management practices. The 
study was laid out in split plot design consisting two factors viz., seedling raising 
methods (wet seed bed and dry seed bed) and N management practices (six N 
treatments) in three replications. Results indicated that both the seedling raising 
methods and N management practices had significant effect on all the yield 
contributing characters of transplanted Aus rice under tidal condition. 
Specifically, the combination of seedlings raised in wet seed bed and fertilized 
with urea super granule (USG) at 10 days after transplanting (DAT) i.e., N3W 
showed the best values for plant height (110.33cm), number of effective tillers 
hill-1 (14.60), days required 50% flowering (53.00 DAT), days to maturity (84.33 
DAT), panicle length (23.37 cm), number of filled grain panicle-1 (88.13), 1000-
grain weight (43.17 g), grain yield (4.62 tha-1), straw yield (6.07 tha-1), biological 
yield (10.67 tha-1), and harvest index (43.17%). However, in considering the 
productivity/ grain yield, besides N3W, the whole urea application at land 
preparation along with wet seed bed (N1W) and USG application along with dry 
seed bed (N3D) also produced statistically similar results (p<0.01) and thus all 
these three combinations may be practiced for improving productivity and 
ensuring horizontal expansion of Aus rice in the tidal ecosystem of Bangladesh.  

 

ISSN : 2580-2410 
eISSN : 2580-2119 

 
 

 

Effect of nitrogen management and seedling raising methods on 
the productivity of Aus rice under tidal ecosystem of Bangladesh 
 
Antara Sarker, Swadesh Chandra Samanta, & Gopal Saha 
 
Department of Agronomy, Patuakhali Science and Technology University, Dumki, Patuakhali, 
Bangladesh-8602 
 

 
 
  
  
 
 
 
 
 
 
 
 
 
 
 
 
Introduction 

Rice (Oryza sativa L.) is the most important staple food crops for over half of the 
world’s population and over 759.6 Mt of rice was produced globally in 2017 (FAO 2018). Near 
about 90% of annual rice is produced and consumed in Asia. The average yield in Asia is low 
compared to global mean yield (Haider 2018). More than two billion people in Asia are 
dependent on rice for their livelihood (Xiong et al., 2013). The demand for rice is increasing 
to meet the demand of rising population. And, the possible way to meet this increases 
demand by improvement of rice yield per hectare (Liu et al., 2016). In Bangladesh, about 75% 
of the total cropped area and over 80% of the total irrigated area is occupied by rice (BBS, 
2013). Thus, rice plays a vital role in the livelihood of the people of Bangladesh. There are 

        OPEN ACCESS             International Journal of Applied Biology 

Keyword 
Aus rice,  
Nitrogen 
management,  
Wet seed bed,  
Dry seed bed,  
Tidal ecosystem. 

Article History 
Received 25 March 2020 
Accepted 14 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 

 69 

three rice growing season viz. Aus, Aman & Boro in Bangladesh which are cultivated during 
Kharif-1 (April–July), Kharif-2 (July–November) and Rabi (November–April), respectively. 
After the 1980s, Aus production slowly began to lose priority to the farmers as they shifted 
to irrigated Boro rice cultivation due to its higher yield (BRRI 2011). The Government of 
Bangladesh has given top priority for increasing the area and production of Aus rice to reduce 
the pressure on electricity for irrigation needed for Boro rice production during dry season. 
Compare to Boro, Aus requires less irrigation and the plan is to cut dependency on the 
underground water for irrigation and arrest the fall in the water level in the aquifer. Aus rice 
in this regard can create scope by scaling up production and shed dependency on the 
underground water (UNB 2017). But the main drawback is the average yield of Aus rice (2.16 
t ha-1) which is lower than Aman and Boro rice (BBS 2013). Using the latest high yielding 
varieties of transplanted Aus rice along with improved cultivation techniques might be the 
best possible options to meet this productivity gap of Aus rice. Bangladesh occupies most 
lands of the great Bengal plane of the Ganges Delta with affluent alluvial soils. And, the overall 
natural climate and geographic condition of Bangladesh is blissful for growing Aus rice. The 
main problem is insufficient rainfall in April-May with which wet nursery bed preparation and 
transplanting is very difficult. So, preparation of wet nursery bed and transplant Aus rice 
seedlings using the tidal water may be a good option. Since water is not easily available and 
time of Aus planting uncertain, dry nursery bed may be alternative option by the farmers of 
tidal area. However, till date there is no such comparative study on the yield variability of 
transplanted rice between wet and dry nursery bed.   

Besides, the management of nitrogenous fertilizer (either as basal or top dressing) is 
difficult due to high depth of water during cultivation period. Nitrogen (N) is the key element 
in the production of rice. But, the N management in the tidal areas is always a great challenge. 
To improve rice yield supplementation of N fertilizer under most agro-ecosystem has been 
suggested (Fageria and Santos, 2014). Nitrogen helps to increase rice productivity through 
improving leaf N concentration, photosynthetic rate, delaying leaf senescence, and increasing 
dry matter for grain filling (Hasegawa et al., 1994). Moreover, N may also play great role in 
improving panicle size, grain weight and reducing spikelet sterility (Fageria, 2009). Application 
of N fertilizer in rice has also been reported to significantly increase the grain and straw N 
uptake and N use efficiency (Hassan et al., 2009). Normally, farmers in the developing 
countries apply N in two ways. One is broadcasting of prilled urea (PU), which is the common 
practice in Bangladesh and another is urea deep placement (UDP) in the form of urea super 
granule (USG). It has been reported that compared to UDP, the main problem of PU is the N 
volatilization loss as ammonia (Rochette et al., 2013). Basically the use efficiency of urea is 
very low and the recovery of N, especially in wetland rice field rarely exceeds 40% (De Datta, 
1989). However, minimizing of N losses in the environment was also possible by applying urea 
to plants through the foliage (Giroux 1984 & Millard and Robinson 1990). In several 
researches it has been observed that most of the plants rapidly can absorb liquid urea and 
hydrolyze the absorbed urea in the cytosol subsequently ensure better assimilation in the 
plants’ system which help to increase N use efficiency (Wittwer et al. 1963, Nicoulaud and 
Bloom 1996 and Lam et al. 1996)  

At this point, our present study has been designed to find out the effect of suitable N 
management practices along with different seedling raising methods viz. wet and dry bed on 
the yield and yield contributing characters of tidal Aus rice and thus, to unlock the potentials 
of horizontal expansion of Aus rice cultivation in the coastal areas of Bangladesh. 



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

 70 

 
Materials and Methods 
Experimental location and climate 

The study was carried out at the Agronomy Field Laboratory of Patuakhali Science and 
Technology University (PSTU), Patuakhali, Bangladesh from April to August, 2017. The 
experimental field was located under Ganges Tidal Floodplain Agro-ecological Zone (AEZ) 13. 
This region occupies an extensive area of coastal tidal floodplain land in the south–west of 
the country. The area lies at 0.9 to 2.1 meter above mean sea level. The study area was 
located under the sub-tropical climate, which is specialized by moderately high temperature 
and heavy rainfall during the Kharif-1 (March to August) and Kharif-2 season (April-
September) and low rainfall with moderately low temperature during Robi season (October-
March).  

The experimental field was flooded twice daily by tidal inundation. The magnitude of 
tidal water depth, flow of water and stagnation period of water depends mainly on the moon-
month, wind speed, wind direction and air pressure that attains peak in May-August (Figure 
1). The highest water depth of the field were observed at the beginning and mid of the moon-
month. The data were collected every two days interval from transplanting (14th May) to 
harvesting date (31th July). 

 
Figure 1. Height of water (in cm) in the experimental field of transplant Aus rice from 

transplanting to harvesting 

 
Experimental Procedure 

The study was a two factor experiment with three replications where two sets of 
experimental treatments included in the study as factor-A (six nitrogen management 
practices) and factor-B (two seedling raising methods) have been presented in Table 1. The 
experiment was laid out in a split-plot design where twelve (12) treatment combinations were 
allocated in 36 plots of 8 m2 size (5m x 1.6m). BRRIdhan55, an Aus rice variety developed by 
Bangladesh Rice Research Institute (BRRI) was used as experimental materials.  
 

3 2 2,67 2
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2,33

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15,67

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26,3327,33
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Water Depth (cm)

Date



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

 71 

Table 1. List of treatments used in the experiment 

Factor-A: Six (6) nitrogen management practices 
N0: No nitrogen 
N1: Whole urea at land preparation @ 150kg ha-1as recommended dose 
N2: Urea Super Granule (USG) at Land preparation @ 112 kg ha-1 
N3: USG @ 1.8g (granule) per 4 hill (112kg ha-1) at 10 days after transplanting (DAT) 
N4: 50% urea of recommended dose+ 2% urea spray at 30, 45 and 60 DAT (105 Kg) 
N5: 50% urea of recommended dose at land preparation + Magic growth spray at 30, 45 

and 60 days 

Factor-B: Two (2) seedling raising methods 
W: Wet seedbed 
D: Dry seedbed 

 
Fertilizer management 

The experimental plots were fertilized as per Fertilizer Recommendation Guide BARC 
(2012). Besides, different nitrogenous fertilizers were applied following the procedure as 
mentioned below-   

Urea spray: Liquid urea used in the experiment for foliar spray was prepared by mixing 
2 kg of prilled urea in 100 L of water as per treatment.  The urea was sprayed@ 500L/ha of 
spray volume at 30, 45 and 60 DAT. 

Magic growth spray: Magic growth is a solution of different nutrient elements and it 
contains 10.51% total nitrogen, 5.58% phosphorous, 6.33% potassium, 0.10% sulphur, 0.16% 
zinc, 0.04%copper, 0.0006% iron, 0.006% manganese, 0.25% boron, 0.07% calcium and 
0.007% magnesium. The spray volume of magic growth was prepared by mixing fifty (50) ml 
magic growth with 1L water. This mixture was sprayed @ 500L /ha at 30, 45 and 60 DAT. 

Urea Super Granule (USG): USG fertilizer is manufactured from a physical modification 
of prilled urea (PU) fertilizer. The International Fertilizer Development Center (IFDC) has 
developed it. Its nature and properties are similar to that of urea but its granule size is bigger 
and condensed with some conditions for slow hydrolysis. USG is spherical in shape containing 
46% N which is similar to that of PU. 

 
Preparation of seedbed and sowing 

Wet seed bed (W): Wet nursery bed was prepared under irrigated condition. The soil 
was puddled by three ploughing and cross ploughing with cultivator. The sprouted seeds were 
sown in the prepared seedbeds on 18th April, 2017. The size of seed bed was 15 m2 (length 
5m & width 1.5×2m). 

Dry seed bed (D): The land was first ploughed, cross ploughed and then harrowed until 
a good tilth condition is attained. The seeds were sown in the prepared dry seedbed on 15th 
April, 2017. The seed bed size was 15 m2. 

 
Data collection and statistical analysis 

Different yield and yield contributing data viz. plant height (cm), number of effective 
tillers hill-1, days to first flowering, days to 50% flowering, number of non-effective tillers hill-
1, days to maturity, panicle length (cm), number of filled grains panicle-1, number of unfilled 
grains panicle-1, thousand grain weight (g), grain yield (t ha-1), straw yield ( t ha-1), biological 
yield (t ha-1) and harvest index (%) were collected and analysis of variance (ANOVA) was 
calculated with the help of computer software package MSTAT-C program (Russel 1986). The 



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

 72 

mean differences among the treatments were compared by Duncan’s Multiple Range Test 
(DMRT) at 5% level of significant (Gomez and Gomez 1984). 

 

Results and Discussion  
In our study different nitrogen management practices and seedling raising methods 

were found to have significant roles on all the yield and yield contributing characters of Aus 
rice under tidal ecosystem. The results are presented below in respect to different important 
growth and yield parameters of transplanted Aus rice. 
 
Plant height 
 Nitrogen management had significant effect on plant height (p<0.01; Figure 2). Among 
all the N management treatments, maximum plant height (109.17 cm) was observed in N3 
treatment [USG @ 1.8g (granule) per 4 hill (112kg/ha) at 10 DAT] and the shortest plant (97.73 
cm) was recorded in case of N0 treatment (without nitrogen) (Figure 2). Our data is also in 
accordance with Ilaga and Daya (1989) regarding plant height in response to nitrogenous 
fertilizers. Plant height was also significantly influenced by seedling raising methods (p<0.01; 
Figure 2) where in case of seedlings raised in wet seed bed were found as longest  (104.23cm) 
compared to the seedlings raised in dry seed bed (99.61 cm). Interaction of nitrogen 
management and seedling raising methods had significant effect on plant height of Aus rice 
(p<0.01; Table 2). The maximum plant height (110.33 cm) was found in N3W treatment 
combination i.e., USG at 10 DAT in combination for the seedlings raised in wet bed and the 
lowest plant height (94.00 cm) was obtained in N0D treatment i.e. without nitrogen in case of 
the seedlings raised in the dry bed. We also observed highest plant height of 108.00 cm from 
the treatment N3 the raised seedlings in dry bed (N3D) which was statistically at par with N3W. 
Using of the urea deep placement technology (USG) has already proven increased yield in 
several studies (Bandaogo et al., 2015; Alam et al., 2013; Gregory et al., 2010; Mohanty et al., 
1999; Savant and Stangel, 1990). Increased plant height might be the response of enhanced 
availability of nitrogen from USG. 
 

 
Figure 2. Effect of different nitrogen management practices and seedling raising 

methods on the plant height of transplant Aus rice. (N0= No nitrogen, N1=Whole urea at 

land preparation @ 150kg/ha, N2=USG at LP @ 112 kg/ha, N3= USG @ 1.8g (granule) 

per 4 hill (112kg/ha) at 10 DAT, N4= 50% urea + 2 % urea spray at 30, 45 and 60 DAT, 

N5=50% urea at land preparation + Magic growth spray at 30, 45 and 60 days). Same 

letter on the bars do not differ significantly as per DMRT (p<0.01). 



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

 73 

 
Table 2. Interaction effect of nitrogen management and seedling raising methods on plant 
height and effective tillers of transplant Aus rice 

Interaction Plant height (cm) No. of effective tillers hill-1 

N0W 101.47 bc 13.13 ab 

N1W 103.67 b 14.47 a 

N2W 103.33 b 13.33 ab 

N3W 110.33 a 14.60 a 

N4W 103.90 b 14.40 

N5W 102.67 bc 13.77 ab 

N0D 94.00 c 10.73 c 

N1D 100.07 bc 13.07 ab 

N2D 97.53 bc 12.33 b 

N3D 108.00 ab 14.20 a 

N4D 97.70 bc 11.93 bc 

N5D 100.33 bc 13.33 ab 

Significance  level ** ** 

CV (%) 4.30 8.85 

Note: In a column, figures with same letter or without letter do not differ significantly as per 
DMRT; ‘**’ = Significant at 1%; N0= No nitrogen, N1=Whole urea at land preparation @ 
150kg/ha, N2=USG at LP @ 112 kg/ha, N3= USG @ 1.8g (granule) per 4 hill (112kg/ha) at 10 
DAT, N4= 50% urea + 2 % urea spray at 30, 45 and 60 DAT, N5=50% urea at land preparation + 
Magic growth spray at 30, 45 and 60 days. W=wet seed bed and D=Dry seed bed; CV (%) = 
Percent coefficient of variation. 
 
Effective tillers hill-1 
 In case of effective tillers per hill, the effect of different N management options were 
highly significant (p<0.01; Figure 3).  The maximum number of effective tillers hill-1 (14.40) 
was observed from the application of USG at 10 DAT (N3) and the lowest number of effective 
tillers hill-1 (11.93) was found from no nitrogen treatment (N0). Adequacy of nitrogen from 
USG probably favored the cellular activity during tiller formation and development, which led 
to increased number of effective tillers hill-1.  
 
 



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

 74 

 
Figure 3. Effect of different nitrogen management practices and seedling raising methods 
on effective tillers hill-1 of transplant Aus rice. (N0= No nitrogen, N1=Whole urea at land 
preparation @ 150kg/ha, N2=USG at LP @ 112 kg/ha, N3= USG @ 1.8g (granule) per 4 hill 
(112kg/ha) at 10 DAT, N4= 50% urea + 2 % urea spray at 30, 45 and 60 DAT, N5=50% urea 
at land preparation + Magic growth spray at 30, 45 and 60 days). Same letter on the bars 

do not differ significantly as per DMRT (p<0.01). 
 

Ahmed et al. (2005) also reported that number of effective tillers hill-1 increased with 
the better management of nitrogen. Again, between the two seedling raising methods the 
number of effective tillers hill-1 was also significantly influenced. In case of wet seed bed 
raised seedling the highest number of effective tillers was recorded (13.95) while this number 
in case of dry seed bed raised seedlings was  12.60 (Figure 3). The interaction effect of 
nitrogen management and seedling raising method on number of effective tillers hill-1 was 
significant (Table 2). The number of effective tillers hill-1 ranged from 10.73 to 14.60 over the 
treatments. The highest number of effective tillers hill-1 (14.60) was obtained with N3W which 
was statistically similar to N4W and N1W and the lowest number of effective tillers hill-1 
(10.73) with N0D. Increased N absorption had great role in increasing number of tillers per 
square meter (Yoshida et al. 1972).  

Days to 50% flowering and maturity 
Different N management practices had significant effect on flowering and maturity of 

transplant Aus rice var. BRRIdhan55 (p<0.05; Table 3). The lowest days required for 50% 
flowering and maturity (50.50 and 78.33 DAT, respectively) were observed in the plants 
treated with N4 (50% urea + 2 % urea spray at 30, 45 and 60 DAT) while highest days were 
recorded from the treatment N3 (USG at 10 DAT) treated plots which were 52.50 and 82.50 
DAT, respectively. In case of the two seedling raising methods, we observed significant 
variation for days to 50% flowering (p<0.05; Table 4) which was 51.83 DAT in wet seed bed 
seedlings and 51.07 DAT in the dry seed bed seedlings. Nitrogen management and seedling 
raising methods had significant effect on time required for 50% flowering (p<0.01; Table 5). 
The treatment combinations of N4D (N4= 50% urea + 2 % urea spray at 30, 45 and 60 DAT with 
dry seedbed) and N5D (50% urea at land preparation + Magic growth spray at 30, 45 and 60 
DAT with dry seedbed)  required the lowest days to 50% flowering (50.33 DAT). The highest 
time period for 50% flowering was required in case of treatment combination N3W (53.00 
DAT). We also found significant variation in attaining maturity due to interaction between 
nitrogen management and seedling raising method (Table 5). N4W required the lowest 

11,93

13,77
12,83

14,4
13,17 13,55

0

2

4

6

8

10

12

14

16

N0 N1 N2 N3 N4 N5

N
o

. 
o

f 
e

ff
e

ct
iv

e
 t

ill
e

rs
 p

e
r 

h
ill

Nitrogen management practices

13,95
12,6

0

2

4

6

8

10

12

14

Wet seed bed Dry seed bed

N
o

. 
o

f 
e

ff
e

ct
iv

e
 t

ill
e

rs
 p

e
r 

h
ill

a 
b 

a b c d e 
f 



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

 75 

duration for 80% maturity (78.00 DAT) and N3W needed the longest duration (84.33 DAT). 
The level of nitrogen in rice field might influence the flower initiation and maturity of T. Aus 
rice. The flowering and maturity dates were significantly influenced by different N 
management in several studies (Rahman et al. 2016; Halder 2013 and Rahman et al. 2005). 
 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

  

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76 

Table 3. Effect of nitrogen management practices on different yield and yield contributing attributes of transplant Aus rice 

Treatment 
Days to 

50% 
flowering 

Days to 
Maturity 

No. of 
filled 
grains   

panicle-1 

No. of 
unfilled 
grains 

panicle-1 

Panicle 
length 
(cm) 

1000-
seed 

weight 
(g) 

Grain 
yield 
(t/ha) 

Straw 
yield 
(t/ha) 

Biological 
yield (t/ha) 

Harvest 
index (%) 

N0 51.33 b 79.67 f 55.80 f 27.40 a 19.98 f 19.98 f 2.94 f 5.07 f 8.01 f 35.32 f 

N1 51.50 b 80.67 b 65.27 b 24.47 d 21.78 b 20.18 b 3.96 b 5.76 b 9.66 b 40.58 b 

N2 51.83 b 80.83 c 61.70 e 25.63 b 20.62 e 20.05 e 3.38 e 5.41 e 8.78 e 38.33 e 

N3 52.50 a 82.50 a 78.20 a 20.60 f 22.70 a 20.32 a 4.23 a 5.88 a 10.10 a 41.65 a 

N4 50.50 d 78.33  e 62.00 d 25.23 c 21.33 d 20.12 d 3.60 d 5.53 d 9.13 d 39.32 d 

N5 51.00 c 78.67 d 63.60 c 23.37 e 21.45 c 20.15 c 3.74 c 5.66 c 9.38 c 39.83 c 

Significance  level * * ** ** ** * ** ** ** ** 

CV (%) 2.05 2.88 7.85 8.85 5.10 3.49 8.97 7.55 7.13 3.75 

Note: In a column, figures with same letter or without letter do not differ significantly as per DMRT; ‘ *’ and ‘**’ = Significant at 5 and 1%, 
respectively ; N0= No nitrogen, N1=Whole urea at land preparation @ 150kg/ha, N2=USG at LP @ 112 kg/ha, N3= USG @ 1.8g (granule) per 4 hill 
(112kg/ha) at 10 DAT, N4= 50% urea urea + 2 % urea spray at 30, 45 and 60 DAT, N5=50% urea at land preparation + Magic growth spray at 30, 
45 and 60 days. CV (%) = Percent coefficient of variation 

 
 
 
 



                  
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77 

Number of filled grains panicle-1 
Nitrogen management showed significant variation in the number of filled grains 

panicle-1 (p<0.01; Table 3). The highest number of filled grains panicle-1 (78.20) was obtained 
from the N3 i.e., USG at 10 DAT and the lowest number of filled grains panicle-1 (55.80) was 
obtained from the no urea treated plot. This finding is in contrast with the findings of 
Rajarathinam and Balasubramanivan, (1999) where they found application of N increased 
number of filled grains panicle-1. The average number of filled grains panicle-1 was found 
significantly different in seedling raising method (p<0.01; Table 4). The highest number of 
filled grains was recorded in the wet seed bed (71.07) and lowest filled grains were in dry 
seed bed (57.79). Interaction effect between nitrogen management and seedling raising 
method had positive effect on filled grains panicle-1 (Table 5). The highest number of filled 
grains (88.13) was obtained from N3W i.e., when USG applied at 10 DAT in combination with 
the seedlings raised in wet bed and the lowest number of filled grains panicle-1 (50.33) was 
obtained from N0D i.e. without nitrogen in case of the seedlings raised in the dry bed. Our 
result suggests that highest number of grains panicle-1 might be the response of enhanced 
availability of nitrogen from USG especially when it applied at 10 DAT.  Subsequently, higher 
available N might results more photo assimilates and thus produced more dry matter 
accumulation in the panicle. These findings are also consistent with the findings of other 
researchers (Alam et al., 2013; Bandaogo et al., 2014; Gregory et al., 2010). 
 
Number of unfilled grains panicle-1 

The number of unfilled grains per panicle was significantly different in the nitrogen 
management (Table 3). The maximum number of unfilled grains per panicle (27.40) was 
counted in case of no nitrogen and the minimum number of unfilled grains panicle (20.60) 
was counted in the N3 i.e., USG at 10 DAT. Nitrogen took part both in grain formation and 
development and for this reason number of grains per panicle increased with adequate N 
levels. This result is in conformity with Halder (2013) and Nori et al., (2008). In case of seedling 
raising methods, number of unfilled grains per panicle was higher in wet seed bed (24.46) and 
minimum unfilled grains per panicle in dry seed bed (24.44; Table 4). Number of unfilled 
grains per panicle was found to be significantly affected by interaction effect of nitrogen 
management and seedling raising method (Table 5). The highest (28.73) number of unfilled 
grains per panicle was recorded under the N4W that was statistically at par with N2D (28.67) 
and N0W (28.40) whereas the lowest number of unfilled grains per panicle (19.87) was 
counted in the treatment combination N3W. 
 
Panicle length (cm) 

The panicle length was significantly affected by nitrogen management practices 
(p<0.01, Table 3). The maximum panicle length (22.70 cm) was observed in USG @ 112 kg/ha 
at 10 DAT and the lowest (19.98 cm) panicle length was obtained from without nitrogen (N0). 
The variation in panicle length due to the improved management of N was also reported by 
Parvin (2012). In our study, both of the seedling raising methods had significant effect on the 
panicle length (p<0.01; Table 4) where highest length of 22.08 cm was recorded in wet 
seedbed compared to plants raised in dry seedbed (20.54cm). Again panicle length was also 
influenced significantly in case of the interaction effect of nitrogen management practices 
and seedling raising methods (p<0.05; Table 5). The longest panicle (23.37 cm) was obtained 
from N3W and the shortest panicle (19.27cm) was obtained from the N2D which was 
statistically similar to N0D (19.43cm).



                  
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78 

Table 4. Effect of seedling raising method on yield and yield contributing attributes of transplant Aus rice 

Seedling raising 
method 

Days to 
50% 

flowering 

Days to 
Maturity 

No. of 
filled 
grains   

panicle-1 

No. of 
unfilled 
grains 

panicle-1 

Panicle 
length 
(cm) 

1000-
seed 

weight 
(g) 

Grain 
yield 
(t/ha) 

Straw 
yield 
(t/ha) 

Biological 
yield (t/ha) 

Harvest 
index (%) 

Wet 
seedbed (W) 

51.83 80.39 a 71.07 a 24.46 a 22.08 a 20.42 a 3.93 a 5.70 a 9.61 a 40.32 a 

Dry 
seedbed (D) 

51.07 79.83 b 57.79 b 24.44 b 20.54 b 19.84 b 3.35 b 5.41 b 8.74 b 38.02 b 

Significance  level NS * ** ** ** * ** * ** ** 
CV (%) 2.05 2.88 7.85 8.85 5.10 3.49 8.97 7.55 7.13 3.75 

Note: In a column, figures with same letter or without letter do not differ significantly as per DMRT; ‘*’ and ‘**’ = Signifi cant at 5 and 1%, 
respectively, NS= Non-significant; CV (%) = Percent coefficient of variation 
 
 
 
 



                  
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79 

Thousand (1000)-seed weight (gm) 
The effect of nitrogen management was significant in respect of 1000-grain weight of 

T. Aus rice (p<0.05; Table 3). The highest 1000-grain weight (20.32 g) was obtained from the 
treatment N3 and the lowest 1000-grain weight (19.98g) was found in control (N0). This 
possibly happened due to the uptake of N by root of the rice plant that influenced the 
photosynthesis process and subsequently storage of starch in sink cell such as grain. USG 
provide the highest amount of available N in the field and created a chance to fill the grain 
properly. Hossain and Islam (2008) also reported the variation in 1000-grain weight due to 
the more availability of N in soil. Chaturvedi (2005) observed that N play important role in 
increasing protein percentage, which in turn increased the grain weight. The weight of 1000-
grains was also significantly influenced (p<0.05; Table 4) by the seedling raising method where 
the seedling raised in wet bed gave higher 1000-grain weight (20.42g) over dry bed method 
(19.84 g). Further, the interaction effect between nitrogen management and seedling raising 
method gave significant variation regarding the weight of 1000-grains (p<0.05; Table 5). The 
treatment combination N2W gave highest 1000-grain weight (20.63 g) which was statistically 
similar with N1W, N3W, N4W, N5W, N3D, N4D and N5D. The lowest weight of 1000-grains (19.47 
g) was obtained from N2D 

Grain yield  
Grain yield was significantly influenced (p<0.01) by nitrogen management practices 

(Table 3). By USG @ 112kg/ha at 10 DAT (N3) produced the highest grain yield (4.23 t ha-1) 
which was followed by the treatments N1, N5, N4, N2 and N0. The lowest grain yield (2.94 t ha-
1) was recorded from without nitrogen (N0). The highest grain yield might be due to the 
resultant effect of highest number of effective tillers per hill and highest number of grains per 
panicle as obtained in the treatment N3. Miah et al. (2006) stated that USG increased an 
average of 20% rice yield in tidal flooded condition. Grain yield variations due to fertilizer 
management were also reported by Shah et al. (2013), Das (2011), Jun et al. (2011) and 
Tahura (2011). Grain yield was also significantly influenced by seedling raising methods (Table 
4). The highest grain yield (3.93 t ha-1) was obtained from the Wet seed bed compared to the 
yield (3.35 tha-1) obtained by the seedlings raised in dry seed bed. Interaction between 
nitrogen management and seedling raising method also played positive role in promoting 
grain yield of transplant Aus rice. Highest grain yield of 4.62 t ha-1 was from the treatment 
combination N3W which was statistically at par with N1W (the whole urea application at land 
preparation along with wet seed bed) and N3D (USG application along with dry seed bed) and 
the lowest grain yield was recorded in N0D (2.56 t ha-1; Table 5). 
 
Straw yield 

Straw yield was significantly (p<0.01) affected by the nitrogen management (Table 3). 
The highest straw yield (5.88 t ha-1) was obtained from the plot applied with USG 112kg/ha 
at 10 DAT (N3) and the least straw yield (5.07 t ha-1) was obtained from the no urea treated 
plot (N0). Availability of nitrogen at vegetative phase during the initiation of primary, 
secondary and tertiary tillers resulted in increased accumulation of dry matter which probably 
favored highest straw yield. Significant variation in straw yield was also reported by Shah et 
al. (2013) and Das (2011). Straw yield was significantly influenced (p<0.05) by the seedling 
raising method (Table 4). The highest straw yield (5.70 tha-1) was obtained from the wet seed 
bed compared to (5.11 t ha-1) dry seed bed. Again, the highest straw yield (6.07 tha-1) was 
recorded from the interaction of seedling raised in wet seed bed and 



                  
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80 

Table 5. Interaction effect of nitrogen management and seedling raising method on yield and yield contributing attributes 
 of transplant Aus rice 

Treatment 
combination 

Days to 50% 
flowering 

Days to 
Maturity 

No. of 
filled 
grains   

panicle-1 

No. of 
unfilled 
grains 

panicle-1 

Panicle 
length 
(cm) 

1000-
seed 

weight 
(g) 

Grain 
yield 
(t/ha) 

Straw 
yield 
(t/ha) 

Biological 
yield (t/ha) 

Harvest 
index (%) 

N0W 51.67 ab 79.67 bc 61.27 c 28.40 a 20.53 b 20.17 ab 3.32 bc 5.25 bc 8.57 bc 36.23 bc 

N1W 
51.67 ab 80.33 ab 77.07 b 22.73 bc 

22.80 ab 20.37 ab 4.24 

ab 

5.91 ab 10.13 ab 41.77 ab 

N2W 52.33 ab 81.67 ab 63.80 bc 22.60 bc 21.97 ab 20.63 a 3.77 bc 5.66 b 9.42 ab 39.93 bc 

N3W 53.00 a 84.33 a 88.13 a 19.87 c 23.37 a 20.50 ab 4.62 a 6.07 a 10.67 a 43.17 a 

N4W 50.67 bc 78.00 c 66.13 bc 28.73 a 21.80 ab 20.47 ab 3.78 bc 5.60 b 9.38 ab 40.23 b 

N5W 51.67 ab 78.33 bc 70.00 24.40 b 22.03 ab 20.40 ab 3.85 bc 5.68 b 9.50 ab 40.60 ab 

N0D 51.00 b 79.67 bc 50.33 d 26.40 ab 19.43 c 19.80 bc 2.56 c 4.89 c 7.45 c 34.40 c 

N1D 51.33 ab 81.00 ab 53.47  cd 26.20 ab 20.77 b 20.00 b 3.67 b 5.61 b 9.18 b 39.40 bc 

N2D 51.33 ab 80.00 b 59.60 cd 28.67 a 19.27 c 19.47 c 2.99 bc 5.15 bc 8.14 bc 36.73 bc 

N3D 
52.00 ab 80.67 bc 68.27 bc 21.33 bc 

22.03 ab 20.13 ab 3.83 

ab 

5.70 ab 9.53 ab 40.13 b 

N4D 50.33 c 78.67 bc 57.87 cd 21.73 bc 20.87 ab 19.77  bc 3.42 bc 5.46 bc 8.88 bc 38.40 bc 

N5D 50.33 c 79.00 bc 57.20 cd 22.33 bc 20.87ab 19.90 bc 3.62 b 5.64 b 9.26 b 39.07 bc 

Significance  level ** * ** ** * * ** ** ** ** 

CV (%) 2.05 2.88 7.85 8.03 5.10 3.49 8.97 7.55 7.13 3.75 

Note: In a column, figures with same letter or without letter do not differ significantly as per DMRT; ‘*’ and ‘**’ = Significant at 5 and 1%, 
respectively and NS= Not significant; N0= No nitrogen, N1=Whole urea at land preparation @ 150kg/ha, N2=USG at LP @ 112 kg/ha , N3= USG 
@ 1.8g (granule) per 4 hill (112kg/ha) at 10 DAT, N4= 50% urea + 2 % urea spray at 30, 45 and 60 DAT, N5= 50% urea at land preparation + Magic 
growth spray at 30, 45 and 60 days. W=wet seed bed and D=Dry seed bed; CV (%) = Percent coefficient of variation 
 



                  
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81 

112kg/ha USG at 10 DAT i.e., N3W (p<0.01) which was statistically similar with N1W (5.91 tha-
1) and N3D (5.70 tha-1). The lowest straw yield (4.89 t ha-1) was recorded in N0D (Table 5). 
 
Biological yield 

Significantly highest (p<0.01) biological yield (10.10 tha-1) was found from USG 
112kg/ha at 10 DAT (N3) and the lowest value (8.01 t ha-1) regarding biological yield was found 
from the no urea treated plot (N0; Table 3). Biological yield was significantly influenced by 
seedling raising method (Table 4) where the maximum biological yield (9.61t ha -1) was found 
in case of wet seed bed and the lowest biological yield (8.74 tha-1) was found from dry seed 
bed. Interaction effect between nitrogen management and seedling raising method was 
significant in respect of biological yield (Table 5). The highest biological yield (10.67 t ha-1) was 
recorded in N3W treatment combination which was statistically at par with the treatment 
combinations N1W, N2W, N4W, N5W and N3D  and the lowest biological yield (7.45 t ha-1) in 
the N0D. 
 
Harvest index 

Nitrogen management produced significant differences (p<0.01) in respect of harvest 
index (Table 3). The highest harvest index (41.65) was found from the N3 treatment and the 
lowest harvest index (35.32) was found from the control (N0). Harvest index was also 
significantly influenced (p<0.01) by the seedling raising method (Table 4). Higher harvest 
index (40.32) was found from the wet seed bed compared to dry seed bed (38.02). In 
considering the interaction effect, nitrogen management and seedling raising method 
significantly highest harvest index (43.17) was recorded in the N3W (p<0.01) which was 
statistically similar with the treatment combinations of N1W and N5W. The lowest harvest 
index (34.40) was observed in case of N0D (Table 5) 

 
Conclusions 

The study concludes that seedlings raised in wet seedbed produced highest grain yield 
with the application of USG at 10 DAT and this was statistically similar to the whole urea 
application at land preparation along with wet seed bed and USG application along with dry 
seed bed. This suggests that wet seed bed preparation with whole urea application at land 
preparation or dry seed bed preparation with USG application at 10 DAT may be practiced for 
cost saving in tidal ecosystem of Bangladesh to avoid the complexity of USG application and 
scarcity of water for wet seed bed preparation. 
 
Acknowledgement 

The authors would like to express their thanks to the Ministry of Science and 
Technology, Bangladesh for providing financial support for conducting the experiment 

 
References 
Ahmed, M., Islam, Md. M & Paul S.K. 2005: Effect of nitrogen on yield and other plant 

characters of local T. aman rice, var. jatai. Research journal of agriculture and biological 

sciences. 1(2): 158-161. 

Bandaogo, A., Bidjokazo, F., Youl, S., Safo, E., Abaidoo, R. & Andrews, O. 2015. Effect of 

fertilizer deep placement with urea supergranule on nitrogen use efficiency in Sourou 



                  
CONTACT : GOPAL SAHA        saha.18@gmail.com 
 

82 

Valley (Burkina Faso). Nutrient Cycling in Agroecosystems. 102: 79–89. 

BBS (Bangladesh Bureau of Statistics) 2013: Yearbook of Agricultural Statistics of Bangladesh. 

Ministry of Planning.Govt. of the People’s Republic of Bangladesh, Dhaka.  p. 136–140.  

BRRI. Bangladesh Rice Research Institute, Government of the People’s Republic of 

Bangladesh, Joydebpur, Gazipur; 2011. 

 Chaturvedi, I. (2005). Effect of nitrogen fertilizers on growth, yield and quality of hybrid rice 

(Oryza sativa). Journal of Central European Agriculture. 6(4): 611-618. 

Das, K.P.B. 2011: Effect of nitrogenous fertilizer on the growth and yield of Boro rice cv. BRRI 

dhan45, MS Thesis, Dept. Agron., Bangladesh Agril. Univ., Mymensingh. 

De Datta, S.K. 1989. Fertilizer management for efficient use in wetland rice soils. International 

Rice Research Institute. Soils and Rice. Los Banos Laguna, Philippines. Ministry of 

Planning, Government of the People’s Republic of Bangladesh. IRRI Conference. 

International Rice Research Institute, P.O. Box. 933, Manila, Philippine. 

Fageria, N.K. 2009. The Use of Nutrients in Crop Plants. CRC Press, Boca Raton, FL, pp. 20–50. 

Fageria, N.K & Santos, A.B. 2014. Lowland rice genotypes evaluation for nitrogen use. Journal 

of Plant Nutrition. 37 (9): 1410–1423. 

FAO. Rice Market Monitor; Food and Agriculture Organization (FAO) of the United Natio ns: 

Rome, Italy, 2018. 

Giroux, M. 1984. Effects d’application d’uree au sol et au feuillage sur le redement, le poids 

spe´cifique et la nutrition azote´e de la pomme de terre. Le Naturaliste canadien. 111: 

157-166. 

Gomez, K. A & Gomez A. A. 1984: Statistical Procedure for Agricultural Research. 2nd ed. John 

Wiley and Sons. New York. 64. 

Gregory, D.I., Haefele, S.M., Buresh, R.J. & Singh U. 2010. Fertilizer use, markets, and 

management. In: Pandey, S., Byerlee, D., Dawe, D., Dobermann, A., Mohanty, S., 

Rozelle, S., Hardy, B. (Eds.), Rice in the Global Economy: Strategic research and policy 

issues for food security. Int. Rice Research Inst, Los Baños, Laguna, Philippines, pp. 231–

263. 

Haider I.K. 2018. Appraisal of biofertilizers in rice: To supplement inorganic chemical fertilizer. 

Rice Science. 25: 357–362. 

 Halder, A. 2013: Effect of PU, USG and NPK Briquette on Yield and Nitrogen Uptake by T. Aus 

Rice (BRRI dhan27). MS Thesis, Dept. soil sci., Bangladesh Agril. Univ., Mymensingh. 

Hasegawa, T., Koroda, Y & Eligman, N.G. 1994. Response to spikelet number of plant nitrogen 

concentration and dry weight in paddy. Agronomy Journal. 86: 673–676. 

Hassan, M.S., Khair, A., Haque, M.M., Azad, A.K & Hamid, A. 2009. Genotypic variation in 

traditional rice varieties for chlorophyll content, SPAD value and nitrogen use efficiency. 

Bangladesh Journal of Agricultural Research. 34 (3): 505–515. 

Hossain, S.M.A & Islam, M.S. 2008: Fertilizer Management in Bangladesh. Advances in 

Agronony Research in Joydebpur, Gazipur. p. 48-54. 

Ilaga, L. G. & Dayag, A. M. 1989. Study on the use of four locally processed organic fertilizer 

in combination with chemical fertilizer on lowland rice. R and D Philippines (Philippines). 



                  
CONTACT : GOPAL SAHA        saha.18@gmail.com 
 

83 

Lam H.M, Coschigano, K.T.,  Oliveira, I.C., Melo-Oliveira, R. & Coruzzi G.M. 1996. The 

molecular-genetics of nitrogen assimilation into amino acids in higher plants. Plant 

Physiology and Plant Molecular Biology. 47: 569-593. 

Liu, X., Wang, H., Zhou, J., Hu, F., Zhu, D., Chen, Z. & Liu, Y. 2016. Effect of N Fertilization 

Pattern on Rice Yield, N Use Efficiency and Fertilizer-N Fate in the Yangtze River Basin, 

China. PLoS ONE 11(11): e0166002. doi:10.1371/journal.pone.0166002  

Miah., M.M.M., Shah, A. L. & Ishaque M. 2006. Nutrient management for different rice 

ecosystem. In proceeding of the workshop on modern Rice Cultivation in Bangladesh. 

12-21 April 2004. Bangladesh Rice Research Institute, Gazipur 1701, Bangladesh. 182-

83. 

Millard, P & Robinson D. 1990. Effect of the timing and rate of nitrogen-fertilization on the 

growth and recovery of fertilizer nitrogen within the potato (Solanum tuberosum L.). 

Fertilizer research. 21: 133-140. 

Mohanty, S.K., Singh, U., Balasubramanian, V & Jha K. P. 1999. Nitrogen deep-placement 

technologies for productivity, profitability, and environmental quality of rainfed 

lowland rice systems. Nutrient Cycling in Agroecosystems. 53:43–57. 

Nicoulaud, B.A.L & Bloom A. J. 1996. Absorption and assimilation of foliarly applied urea in 

tomato. Journal of the American Society for Horticultural Science. 121: 1117-1121. 

Nori H, Halim R. A & Ramlan M. F. 2008: Effect of nitrogen fertilizer management practice on 

the yield and straw nutritional quality of commercial Rice Varieties. Malaysian Journal 

of Mathematical Sciences. 2(2):  61-71. 

Parvin, S. 2012: Improving yield of T. Aman rice (cv. BRRI dhan52 ) through integrated use of 

nitrogen. MS Thesis, Dept.Agron., Bangladesh Agril. Univ., Mymensingh. p. 23-33. 

Rahman, M., Sarker, M. N. H., Akter, F. M. F & Masood M. M. 2005: Comparative yield 

performance of two high yielding rice varieties to different nitrogens levels. Bangladesh 

Journal of Crop Science. 16(1): 73-78. 

Rahman, M. M., Samanta, S. C., Rashid, M. H., Abuyusuf, M., Hassan, M. Z & Sukhi K. F. N. 

2016. Urea super granule and NPK briquette on growth and yield of different varieties 

of aus rice in tidal ecosystem. Asian Journal of Crop Science. 8: 1-12. 

Rajarathinam, P & Balasubramaniyan, P. 1999: Effect of plant population and nitrogen on 

yield attributes and yield of rice (Oryza sativa). Indian Journal of Agronomy. 44(4):  717-

721. 

Rochette, P., Angers, D.A., Chantigny, M.H., Gasser, M.O., Mac-Donald, J.D., Pelster, D.E & 

Bertrand, N. 2013. Ammonia volatilization and nitrogen retention: How deep to 

incorporate urea? J. Journal of environmental quality. 42: 1635–1642. 

Russel, D.F. 1986: MSTAT-C package program. Crop and Soil Sci. Dept, Michigan State Uni, 

USA. 

Savant, N.K. & Stangel P. J. 1990. Deep placement of urea supergranules in transplanted rice: 

Principles and practices. Fertilizer Research. 25:1–83. 

Shah, A.L., Sarker, A. B. S., Islam, S. M. M & Mridha A. J. 2013: Deep placement of NPK 

briquette: Environment friendly technology for rice production. Paper presented at the 



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

 84 

National Workshop on deep placement of NPK briquette, held at BARC, Dhaka on March 

28, 2013 in collaboration with IFDC. 

Tahura, S. 2011: Effect of PM and Nitrogenous Fertilizer on the Growth and Yield of Transplant 

Aman Rice, MS Thesis, Depart. Agron., Bangladesh Agril. Univ., Mymensingh. 

UNB. United News of Bangladesh. Govt launches Tk 336 m incentive to boost Aus production. 

The Financial Express. http://www. thefinancialexpress-bd.com/2016/03/27/23283 

(2016). Accessed 02 Oct 2017. 

Wittwer, S.H., Bukovac, M. J & Tukey H. B. 1963. Advances in foliar feeding of plant nutrients. 

In MH McVickar, ed, Fertilizer Technology and Usage. Soil Science Society of America, 

Madison, WI, pp: 429-455. 

Xiong, J., Ding, C. Q., Wei, G. B., Ding, Y.F & Wang S. H. 2013. Characteristic of Dry-Matter 

Accumulation and Nitrogen-Uptake of Super-High-Yielding Early Rice in China. 

Agronomy Journal. 105(4):1142±50.  

Yoshida, S., Cock, J. H & Parao F. T. 1972. Physiological aspects of high yield. Int. Rice Res. Inst. 

Rice breeding, pp. 455-469.