Submergence tolerance and yield performance of lowland rice as affected by agronomic management practices in eastern India |
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Affiliation: | 1. Department of Ecology, Faculty of Environmental Sciences, Czech University of Life Sciences, Prague, Kamýcká 129, Prague 6, Suchdol CZ165 00, Czech Republic;2. Faculty of Agrobiology, Food, and Natural Resources, Department of Agroecology and Plant Production, Czech University of Life Sciences, Prague, Kamýcká 129, Prague 6, Suchdol CZ165 00, Czech Republic;3. Department of Animal Science and Food Processing in the Tropics, Faculty of Tropical AgriSciences, Czech University of Life Sciences, Prague, Kamycka 129, Prague 6, Suchdol CZ165 00, Czech Republic |
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Abstract: | Rice is subjected to excessive waterlogging and flash-flooding on large areas in south and south-east Asia. Besides cultivars, submergence tolerance of plants is influenced by various agronomic practices. A field experiment was conducted at Cuttack, India during 1994–1995 to study the effect of method of stand establishment (direct seeding and transplanting), vigour of seed (low and high-density) or seedlings (N-fertilized and unfertilized), plant population (normal and 50% more) and N fertilizer (single basal and split application) on yield performance of lowland rice under conditions of natural submergence and simulated flash-flooding (impounding up to 90 ± 3 cm depth for 10 days at vegetative stage). Flooding reached a maximum depth of 80 cm in 1994 and 52 cm in 1995 under natural submergence. The crop performance was better in 1994 due to timely sowing in dry soil and delayed accumulation of water (43 days after sowing) than in 1995 when sowing was done late in saturated soil followed by early water accumulation (28 days after sowing). Grain yield of rice decreased by 30.0–33.6% due to simulated flash-flooding compared with natural submergence, and by 21.4–33.1% due to transplanting in July compared with direct seeding in May-end/early June. The yield of direct-sown crop increased by using high-density seed of 22.9–23.0 mg weight (5.2–9.0%), higher seed rate of 600 m−2 (2.2–2.3%) and basal fertilization at 40 kg N ha−1 (19.4–25.7%) compared with low-density seed (19.4–20.1 mg), 400 seed m−2 and no N, respectively. The yield of transplanted crop increased by using N-fertilized seedlings of 0.49–1.65 g weight (29.5–38.5%), higher number of seedlings at 155 m−2 (3.5–16.7%) and basal fertilization at 40 kg N ha−1 (31.9–32.5%) compared with unfertilized seedlings (0.19–0.79 g), 115 seedlings m−2 and no N. Split application of 40 kg N ha−1 — 50% each at basal and top dressing (105–115 days of growth after flash-flooding) — improved yield significantly (10.1–13.1%) over single basal application under simulated flash-flooding, but not under natural submergence conditions. Regression analysis indicated that relative contribution of various factors in increasing grain yield was in order: N fertilizer > seed density > seed m−2 in direct-sown rice, and N fertilizer > seedlings m−2 > seedling dry weight in transplanted rice. It was concluded that grain yield of flood-prone lowland rice can be increased by establishing the crop early through direct seeding using high-density seed and basal N fertilization. |
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