Research Article

Effect of Age of Seedlings at Staggered Planting and Spacing on Growth and Yield of Transplant Aman Rice (Cv. Brri Dhan 46)

Tipu Sultan*, Rais Uddin Rashed, Shawkat Islam Shawan, Swapan K P and Abdur Rahman Sarkar

Department of Agronomy, Bangladesh Agricultural University, Bangladesh

Submission: August 08, 2018; Published: September 17, 2018

*Corresponding author: Tipu Sultan, Department of Agronomy, Bangladesh Agricultural University, Bangladesh, Email: tipubjri@gmail.com

How to cite this article: Sultan Tipu, Rashed MRU, Shawan SI, Swapan K P, Sarkar AR. Effect of Age of Seedlings at Staggered Planting and Spacing on Growth and Yield of Transplant Aman Rice (Cv. Brri Dhan 46) Adv Biotech & Micro. 2018; 11(2): 555808. DOI:10.19080/AIBM.2018.11.555808

Abstract

An experiment was conducted to observe the effect of seedling age at staggered planting and spacing on the growth and yield of transplant Aman rice cv. BRRI dhan 46. Three seedling ages viz. 30, 45 and 60 days and six spacings viz. 25cm x 5cm, 25cm x 10cm, 25cm x 15cm, 25cm x 20cm, 25cm x 25cm and 20cm x 20cm respectively were included in the experiment using a randomized completely block design with three replications. Growth, yield and yield contributing characters of transplant Aman rice were influenced by seedling age, spacing and their interactions. Forty-five-days old seedlings with 20cm x 20cm spacing produced the tallest plant. At harvest, 45-days old seedlings produced the tallest plant, highest number of non-effective tillers hill-1, highest number of total grains panicle-1, highest grain yield and highest biological yield. Whereas 60-days old seedlings produced the lowest grain yield, straw yield and biological yield and harvest index. The spacing 25cm × 15cm produced the highest grain yield, highest straw yield and highest biological yield. In the interaction between seedling age and spacing the highest grain yield was obtained when 30-day old seedlings were transplanted with 25cm × 20cm spacing, which was statistically identical to 45-days old seedlings at the same spacing. From the results, it may be concluded that 45-days old seedlings transplanted with 25cm× 15cm to 25cm × 20cm spacing appeared as the promising practice to obtain maximum grain yield of transplant Aman rice cv. BRRI dhan46 under staggered transplanting condition.

Keywords: Transplanting; Staggered Planting; Spacing; Harvest index

Introduction

Farmers in Bangladesh generally grow transplant Aman rice by using seedling sown at one time in the nursery bed. But transplanting sometimes late due to unavailable circumstances viz. stagnant water due to flood, delay in land preparation etc. and they have to use the seedling from the same source after recession of flood water, availability of suitable condition for land preparation. Thus, the seedling age increases due to delay in transplanting, though they were sown at the same time. This practice of transplanting seedling at different days having different ages is termed as staggered planting. The age of seedling is an important factor because it has tremendous influence on the growth and development, tiller production, grain formation and other yield contributing characters of rice [1].

For optimum yield, age of seedlings at transplanting of a suitable variety at a particular season may not be suitable for other varieties at another season. The use of over aged seedling ultimately affects the general performance of crop and the yield of the crop reduces drastically. So, it is very important to find out the optimum age of seedlings of a variety for a particular season. Spacing is another important factor that influences the growth, development, yield and yield components of transplanted rice. Optimum plant spacing ensures the plant to grow properly with their aerial and underground parts utilizing more solar radiation and nutrients [2]. When the plant spacing exceeds an optimum level, competition among plants for light becomes severe. Consequently, the plant growth slows down and ultimately the grain yield decreases. The tillering habit and production of spikelets panicle-1 depends to a great extent on the spacing of transplanting which is responsible for the variation of yield in rice.

BRRI dhan46 is a released transplant Aman rice variety. More clarification is needed in case of its agronomic practices and so more investigations are needed to determine the optimum age of seedling and plant spacing for this cultivar. Therefore, an experiment was conducted with the following objectives:

a. To find out the optimum seedling age at staggered planting of the transplant Aman rice cv. BRRI dhan 46;

b. To identify the suitable spacing at staggered planting of the transplant Aman rice cv. BRRI dhan 46 and

c. To observe the interaction effect (if any) between seedling age and plant spacing on the growth, yield and yield components of transplant Aman rice cv. BRRI dhan46.

Material and Methods

The experiment was carried out at the Agronomy Field Laboratory of Bangladesh Agricultural University (BAU) form June 2015 to November 2015 to evaluate the combined effect of seedling age at staggered planting and spacing on the growth and yield of transplant Aman rice cv. BRRI dhan46

Plant material used

BRRI dhan 46, a high yielding cultivar of transplant Aman rice, was used as the test crop in the experiment. This variety was developed by the Bangladesh Rice Research Institute (BRRI) in 2007 as transplant Aman rice.

Transplanting seedlings

Thirty-day old seedlings were transplanted on 10 August 2015 at the rate of 3 seedlings hill-1 with six spacing as per treatment. Forty-five-day old seedlings were transplanted on 25 August 2015 with similar seedling rate and spacing. Then sixtyday old seedlings were transplanted on 14 September 2015 with similar seedling rate and spacing.

Sampling, harvesting and processing

Harvesting was done depending upon the full maturity of crop. Maturity of crop was determined when 90% of the grain became golden yellow color. Five hills from each plot excluding border hills were selected at random prior to harvesting and to record the data on yield attributes. These plants were taken out with respective tag levels. An area of central 5m2 in each plot excluding the crop sampling zone was harvested for measurement of grain and straw yields on 30 November 2015. The harvested crop of each plot was separately bundled, properly tagged and then brought to the threshing floor. Finally, grain and straw yields were adjusted to 14% moisture and converted to t ha-1.

Data collection

Data collection during growth stages

Data were recorded for measuring growth parameters. For this reason, five hills (excluding broader hills) from each plot were selected randomly and tagged for measuring the following characters at 15-day interval beginning 20 days after transplanting (DAT) upto 65 DAT

a. Plant height

b. Number of total tillers hill-1

c. Leaf area Index (LAI)

d. Total dry matter hill-1

Procedure of data collection during growth stages

Plant height and Number of tillers hill-1 Five plants plot-1 were selected randomly and plant height was measured, and Number of tillers was counted at 20, 35 and 50 DAT and 65 DAT, respectively.

Leaf area index

The leaves were collected from destructive samples two hills in each plot and kept in polythene bag then leaf area was measured by using leaf area meter in the central laboratory, BAU. Leaf area was recorded at-15-day intervals beginning from 25 DAT up to 55 DAT. Finally leaf area index was calculated with the following formula (Radford, 1967; Hunt 1978)

Leaf area index (LAI): Ratio of leaf area to its ground area

LAI = LA/P

Where, LA = Leaf area

P = Ground area.

Grain Yield

Grains obtained from five square meter central area of each plot were sun dried and weighed carefully. The grains were weighed and converted to t ha-1. Final grain yield was adjusted at 14% moisture content by using the following formula:

Moisture = Fresh weight Oven dry weight/Fresh weight 100Mc ×10

So, adjusted yield at 14% moisture content = 86 × W (100-14 = 86)

Here, Mc= Moisture content of grain

W= Fresh weight of grain.

Biological yield

Grain yield and straw yield were altogether regarded as biological yield. The biological yield was calculated with the following formula:

Biological yield = Grain yield + Straw yield.

Harvest index

Harvest index is the ratio of economic yield to biological yield and expressed as percentage (%). Harvest index was calculated on the basis of adjusted grain and straw weight using the following formula.

Harvest index (%)= Grain yield/Grain yield Straw yieldX100

Statistical analysis

Data recorded for different parameters were compiled and tabulated in proper form for statistical analysis. The recorded data on various plant characters were statistically analyzed using “Analysis of variance technique” with the help of computer Package program MSTAT and the significance of mean difference was adjudged by Duncan’s Multiple Range Test [3].

Results and Discussion

The Analysis of Variance (ANOVA) showed significant results in different parameters.

Growth parameters

Plant height

A. Effect of seedling age at staggered planting

Plant height was significantly influenced by seedling age and 20 DAT, the highest plant height (52.96cm) was obtained from 60-day old seedlings which was statistically identical to 45-day old seedlings and the lowest plant height (31.54cm) was obtained from 30-day old seedling. At 35 DAT, the highest plant height (79.63cm) was recorded from 45-day old seedlings which was statistically identical to 30- day old seedling and the lowest plant height (62.98cm) was obtained from 30- day old seedlings. At 50 DAT, the highest plant height (93.84cm) was obtained from 30- day old seedlings which was statistically identical to 45-day old seedlings and the lowest plant height (78.78cm) was obtained from 60-day old seedling. At 65 DAT, the highest plant height (105.65cm) was obtained from 45-day old seedlings which was statistically identical to 30-day old seedlings and the lowest plant height (95.18cm) was obtained from 60-day old seedlings (Figure 1).

B. Effect of spacing

The results showed that the plant height was not significantly affected due to the spacing (Figure 2).

C. Effect of interaction between seedling age and spacing

Plant height was significantly influenced due to the interaction between seeding age at staggered planting and spacing at 65 DAT. At 65 DAT, the highest plant height (111.33cm) was obtained at 20cm × 20cm spacing with 45-day old seedling which was statistically identical to 25cm × 10cm, 25cm × 15cm, 25cm × 20cm spacing with 45-day old seedling.

Number of panicles hill-1

A. Effect of seedling age at staggered planting

Number of panicles hill-1 was significantly influenced due to age of seedling. The highest number of panicles hill-1 (8.17) was obtained from 30-day old seedling which was statistically identical to 45-day old seedling. The lowest number of panicle hill-1 (7.2) was obtained from 60-day old seedling.

B. Effect of spacing

The results showed that number of panicles hill-1 was not significantly affected due to spacing.

C. Effect of interaction between seedling age and spacing

The results showed that number of panicles hill-1 was not significantly affected due to interaction between seedling age and spacing.

Number of grains panicle-1

A. Effect of seedling age at staggered planting

The effect of seedling age on grains panicle-1 was found to be significant. The highest number of grains panicle-1 (92.19) was obtained from 30-day old seedlings, which was statistically identical to 45- day old seedling. The lowest number of grains panicle-1 (80.86) was obtained from 60-day old seedlings.

B. Effect of spacing

The results showed that spacing had significant effect on the production of grains panicle-1. Wider spacing of 25cm × 25cm produced the highest number of grains panicle-1 (95.65) which differed from other treatments. The lowest number of grains panicle-1 (85.23) was obtained from closer spacing of 25cm × 5cm. From the results it was observed that wider spacing produced more number of grains panicle-1 than closer ones.

C. Effect of interaction between seedling age and spacing

Number of grains panicle-1 was significantly influenced due to seedling age and spacing. The highest number of grains panicle-1 (106.41) was obtained from 25cm × 25cm spacing and 45-day old seedlings. The lowest number of grains panicle-1 (70.74) was obtained from 60-day old seedling with 25cm × 10cm spacing.

Weight of 1000 grains

A. Effect of seedling age

The weight of 1000 grains were significantly influenced due to age of seedling. The highest weight of 1000 grains (25.38g) was obtained from 30-day old seedlings, which was statistically identical to 45-day old seedlings. The lowest weight of 1000 grains (22.48g) was obtained from 60-day old seedlings.

B. Effect of spacing

The weight of 1000 grains had no significant effect due to spacing (Appendix IV). This result is in agreement with the findings of Hwua and Theseng (1982) who stated that spacing had no significant effect on 1000-grain weight.

C. Effect of interaction between seedling age and spacing

The interaction between seedling age and spacing exerted no significant effect on 1000-grain weight.

Grain yield

Grain yield was significantly influenced by seedling age. The highest grain yield (4.51 t ha-1) was obtained from 45-day old seedlings. The lowest grain yield (3.98 t ha-1) was obtained from 60-day old seedlings which was statistically identical with 30- day old seedlings.

Effect of spacing

Spicing had significant effect on grain yield. The highest grain yield (4.76 t ha-1) was obtained from wider spacing of 25cm ×15cm. The lowest grain yield (4.01 t ha-1) was obtained from closer spacing of 25cm × 5cm. The results showed that grain yield increased with increasing spacing.

B. Effect of interaction between seedling age and spacing

Grain yield was significantly influenced by the interaction between seedling age and spacing. The highest grain yield (4.84 t ha-1) was obtained from 30-day old seedlings with 25cm × 15cm spacing. The lowest grain yield (3.67 t ha-1) was obtained from 30-day old seedlings with 20cm × 20cm spacing.

Biological yield

A. Effect of seedling age at staggered plantings

Biological yield was significantly influenced by seedling age. The highest biological yield (11.62 t ha-1) was obtained from 45-day old seedlings. The lowest biological yield (10.21 t ha-1) was obtained by transplanting 30-day old seedlings, which was statistically identical to 60-day old seedling.

B. Effect of spacing

Spacing had significant effect on biological yield. The highest biological yield (11.57 t ha-1) was obtained from wider spacing (25cm × 15cm). The lowest biological yield (10.20 t ha-1) was obtained from closer spacing (25cm × 10cm) the result showed that wider spacing produced more biological yield than wider spacing.

C. Effect of interaction between seedling age and spacing of transplanting

The interaction effect of seedling age and spacing was significant on biological yield. The highest biological yield (13.43 t ha-1) was obtained from 45-day old seedlings with 20cm × 20cm spacing. The lowest biological yield (8.23 t ha-1) was obtained from 30-day old seedlings with 20cm × 20cm spacing.

Harvest index

A. Effect of seedling age at staggered planting

Harvest index was significantly influenced due to seeding age. The highest harvest index (40.66%) was obtained by transplanting 30-day old seedlings. The lowest harvest index (37.92%) was obtained from 60-day old seedling which, was statistically identical to 45-day old seedling.

B. Effect of spacing

The results showed that harvest index was not significantly affected due to spacing.

C. Effect of interaction between seedling age and spacing

The interaction effect between seedling age and spacing was significant on harvest index. The highest harvest index (42.28%) was obtained from 30-day old seedlings with 25cm × 10cm spacing. The lowest harvest index (35.56%) was obtained from 60-day old seedlings with 25cm × 5cm spacing.

Conclusion

Its observed that, forty-five days old seedlings and 20cm × 20cm spacing produced the tallest plant at 65 DAT. Forty-five-day old seedlings produced the tallest plant, highest number of total spikelets panicle-1, highest grain yield and highest biological yield. Whereas 60-day old seedlings produced the lowest grain yield, straw yield and biological yield and the lowest harvest index.

All parameters studied at harvest were significantly influenced due to spacing except length of panicle, number of panicles hill- 1, 1000-grain weight and harvest index. Wider spacing of 25cm × 25cm produced the highest plant height, highest number of effective tillers hill-1, highest number of non-effective tillers hill- 1 and highest number of grains panicle-1, which were similar to 25cm × 15cm spacing. Spacing of 25cm × 15cm produced the highest grain yield, highest straw yield, highest biological yield. Whereas the closer spacing of 15cm× 5cm produced the shortest plant, lowest number of tillers hill-1, lowest number of effective tillers hill-1, highest non-effective tillers hill-1 and lowest grain yield, straw yield and biological yield. The interaction of seedling age and spacing had significant effect on most of the parameters except plant height and 1000 grain weight. In the interaction between seedling age and spacing the highest grain yield was obtained when 30-day old seedlings were transplanted with 25cm × 20cm spacing, which was statistically identical to 45- day old seedlings at the same spacing. The lowest grain yield, straw yield and biological yield were obtained from 30-day old seedlings with 20cm × 20cm spacing.

From the results of the present experiment it may be concluded that 45-days old seedlings transplanted with 25cm× 15cm to 25cm × 20cm spacing appeared as the promising practice to obtain maximum grain yield of transplant Aman rice cv. BRRI dhan46 under staggered transplanting condition [4-6].

References

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