Effect of Border on Yield Component and Yield of Rice

Border effect in rice

Effect of Border on Yield Component and Yield of Rice

M.A.K. Mian, Principal Scientific Officer,

Agronomy Division, Bangladesh Agricultural Research Institute, Gazipur 1701

Introduction

Border is the outer margin or side of a plot or crop field. Outer margin of crop field is exposed more as compared to inner side of the plot. Plants in the outermost row next to the unplanted alley showed a general increase in yield and growth as compared with the center row. This phenomenon has been referred to as 'border effect'. Main causes of border effect are considered to be advantageous environmental factors above the ground, such as higher solar energy, air circulation etc. Consequently, crop plants of border get more light and more opportunity for gaseous exchange like carbon di oxide intake and release of oxygen. Transpiration of crop plant is also influenced by border. Crop plants of border get more aeration as compared to inner side of the plot. More light enhanced photosynthesis of crop plants of border. More photosynthesis results in more dry matter production in the plant system ultimately contributes to higher yield of crop. Thus physiological process of yield formation of crop plant is influenced by border effect. There are scientific evidences of border effect on crop yield. But research on border effect of crop as well rice in Bangladesh is scanty. Therefore the study was undertaken to quantify the border effect on rice.    

Materials and Method

The experiment was conducted at Agronomy Research Field of Bangladesh Agricultural Institute, Gazipur during 2019 to quantify the border effect on rice. The experiment was set in a randomized complete design with twenty four replication. The treatment was non border (T₁) and border (T₂). Unit plot size was 5 m×5 m. Plant spacing was maintained as 25 cm ×15 cm (row to row 25 cm and hill to hill 15 cm).  The land was prepared well by power tiller. Twenty eight day old seedling of BRRI dhan71 was transplanted on 28 July 2019 and the crop was harvested on 25 October (border) and 28 October (non border). The crop was fertilizer as per recommendation of BRRI (2014). Other intercultural operations were done as and when necessary. Date of anthesis and maturity (with photograph) was recorded.  Data was recorded of border (2 lines around the plot) and non border (excluding 2 lines around the border) treatment. Sixty hill per treatment was cut randomly at the base of rice plant for yield component. Hundred panicle was selected for number of grains/panicle and length of panicle measurement. Grain growth was calculated on the basis of 1000-grain weight and duration of maturity required after anthesis. Yield was recorded on the basis border (2 lines around the plot) and non border (excluding 2 lines around the border) area of each plot (total 24). Grain yield of rice was adjusted at 12% moisture level. Collected data was subjected to statistical analysis and significant level indicated the variation between two treatments.      

Results and Discussion

Plant height, tillers/plant, length of panicle, total grains/panicle, filled grains/panicle, unfilled grains/panicle, weight of 1000-grain, duration of maturity after anthesis, grain growth, grain weight/panicle, grain yield, straw yield and harvest index of rice were significantly varied between non border and border treatment (Table 1 and Table 2). Tillers/hill, Length of panicle, total grains/panicle, Filled grains/panicle were observed higher in border treatment but plant height and unfilled grain/panicle were higher in non border treatment (Table 1). The weight of 1000-grain, grain growth, grain weight/panicle, grain yield, straw yield and harvest index was recorded higher in border treatment whereas duration of maturity after anthethis was lower as compared to non border treatment (Table 2). Grain yield increased 8% due to border effect as compared to non border.  

Conclusion

Border effect was estimated at 8% in border area. Two lines of rice hill should be excluded for harvesting of plot yield. Otherwise 8% yield will be deducted in the border area (2 lines of hill around the plot) for actual yield calculation.

Table 1. Plant height, tillers/plant, length of panicle, total grains/panicle, filled grains/panicle and

                unfilled grains/panicle of rice under non border and border treatment (2019)

Treatment	Plant height (cm)	Tillers/hill (no.)	Length of panicle  (cm)	Total grains/panicle (no.)	Filled grains/panicle (no.)	Unfilled grains/panicle (no.)
Non Border	122	12.0	26.57	164	121	42
Border	117	14.20	27.92	193	179	12
LS	**	**	**	**	**	*
CV (%)	1.57	9.52	3.58	2.53	4.27	17.05

    

       LS=Level of significance, **Significant at 1% level of probability and * Significant at 5% level of probability

Table 2. Weight of 1000 grain, duration of maturity after anthesis, grain growth, grain weight/panicle,

                grain yield, straw yield and harvest index of rice under non border and border treatment 
                (2019)

Treatment	Weight of 1000 grain (g)	Duration of maturity after anthesis (days)	Grain growth (mg/grain/day)	Grain weight/ Panicle (g)	Grain yield (t/ha)	Straw yield (t/ha)	HI (%)
Non Border	25.78	30 (120)	0.86	3.09	6.12	8.67	41.36
Border	26.03	27 (127)	0.96	4.47	6.61	8.96	42.45
LS	**	**	*	*	**	*	**
CV(%)	1.62	5.11	9.22	6.13	8.56	10.25	2.64

        Values in parenthesis indicates the total life period,

         LS=Level of significance, **Significant at 1% level of probability and * Significant at 5% level of probability

Improving Crop Productivity in Beel areas of Bangladesh (ID-688, NATP-2, BARC)

Name of Technology: Improving Crop Productivity in Beel areas of Bangladesh

Introduction:

Beel (Low land goes under water and remains under water about 4-5 months generally from July to November) area are under unfavourable ecosystem covering an area of 2.43 million hectares in Bangladesh. Beel is less productive and remains fallow in most of the part of the year. Boro rice is the main crop in beel area but it requires huge amount of water. There is a possibility of improving crop productivity through adaptation of HYV of crops in the cropping pattern along with their production technologies. Hence, alternate cropping rather than boro rice can improve crop productivity and save underground water resource. In this context, short duration mustard before boro rice and broadcast aman rice after boro rice can improve the cropping pattern in Beel area. Rattoon rice of aus rice and intercropping of Garlic+ Watermelon are two important ways to improving crop productivity in beel area. Moreover, improve varieties of wheat, maize, mustard, garlic, lentil and onion can increase yield. On the basis of research findings of the project factsheet of technology has been made.

Description of the Technology:

v  Eight crop varieties (BARI Sarisha-14, BARI Sarisha-15, BARI Gom-30, Maize var. NK-40, 900 M Gold and Miracle, BARI Rashun-3 and BARI Piaj-4) were found suitable for increasing crop yield in Beel area. 

v  Short duration mustard (var. BARI Sarisha-14) before boro rice, broadcast aman rice (cv. modhudigha) after boro rice, dibbing technique for maize (var. NK-40), Garlic+ Watermelon intercropping are important ways of improving crop productivity in Beel area.

v  Sowing time of crops depends on recession of water: 1-15 November (mustard), 15 November-5 December (maize, wheat, garlic), 15 December-20 January (onion) are suitable sowing time in Beel area.

v  Fertilizer dose like 325-90-185-60-5-2.5 kg/ha of N-P-K-S-Zn-B + Weeding at 20 days after emergence (DAE) (Grain yield: 12.98 t/ha and BCR: 2.24) for maize, Fertilizer dose of 140-44-70-30-1.8-1 kg/ha of N-P-K-S-Zn-B + Weeding at 15 DAE for mustard (Seed yield: 1.75 t/ha and BCR: 1.69), Fertilizer dose like 125-190-206-25-5 -2.5 kg/ha of N-P-K-S-Zn-B + Weeding at 30 days after dibbling (Garlic equivalent yield: 25.22 t/ha and BCR: 2.84) for Garlic+ Watermelon intercropping were found suitable.

v  Fertilizer dose of 125-45-31-25-2-1 kg/ha of N-P-K-S-Zn-B + Weeding at 20 DAE for wheat (Grain yield: 5.52 t/ha and BCR: 1.81), Fertilizer dose like 150-75-200-50-5.6-2.5 kg/ha of N-P-K-S-Zn-B + Weeding at 30 DAE for onion (Bulb yield (19.96 t/ha and BCR: 2.01) were found suitable for higher yield and BCR.

v  Fertilizer dose of 40-20-10-5-0.8-0.5 kg/ha of N-P-K-S-Zn-B + Weeding at 5-7 days after harvest of main rice for ratooning (Grain yield: 2.10 t/ha and BCR: 3.82), and Fertilizer dose of 26-11-11-5-0.8-0.8 kg/ha of N-P-K-S-Zn-B + Hand weeding at 20 DAE and 50-60 DAE (Grain yield: 1.59-1.61 t/ha and BCR: 1.91-2.11) for B. aman rice were found profitable in beel area.

v  Weeding (15-18 DAE for mustard, 20 DAE for wheat, 20-25 DAE for maize, 30 DAE for garlic, 30 DAT for onion, 20 DAE for B. aman, 5-7 days after harvesting (DAH) for ratoon rice) and irrigation (1 for mustard, 2 for wheat and 3 for maize, 2-3 for onion and garlic) was done as and when necessary. 

v  Harvesting of crops: 6-12 February (Mustard), 27-30 March (Wheat), 15-19 April (Maize), 25 March-8 May (onion and garlic), 30 November (Ratoon rice), 7-13 December (B. aman rice) are optimum harvesting time of crops in Beel area.    

Benefit of the Technology:

  Crops varieties like maize var. NK-40, 900 M Gold and Miracle (Grain yield: 10.02-10.64 t/ha and BCR: 1.88-2.00), mustard var. BARI Sarisha-14 (Seed yield: 1.67 t/ha and BCR: 1.65) and BARI Sarisha-15 (Seed yield: 1.60 t/ha and BCR: 1.59), wheat var. BARI Gom-30 (Grain yield: 5.02 t/ha and BCR: 1.78), garlic var. BARI Rashun-3 (Bulb yield: 12.54 t/ha and BCR: 1.64), onion var. BARI Piaj-4 (Bulb yield: 19.61 t/ha and BCR: 2.00) showed better yield performance and economic return in beel area.

  Cultivation of short duration mustard variety (BARI Sarisha-14) before boro rice and broadcast (B.) aman rice after boro rice can increase crop productivity as well as cropping intensity in Beel areas of Bangladesh. Future research needs in the aspect.