Seeding, nitrogen and irrigation management optimize rice water and nitrogen use efficiency

Seeding, nitrogen and irrigation management optimize rice water and nitrogen use efficiency

Adoption of appropriate agronomic practices, such as optimum seeding and nitrogen (N) rates, in synchronization with proper water management practice could help improve yield, water productivity and N use efficiency (NUE) of rice ( Oryza sativa L.). Field experiments were conducted at the research f...

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Bibliographic Details
Published in:Nutrient cycling in agroecosystems Vol. 120; no. 3; pp. 325 - 341
Main Authors: Santiago-Arenas, Raquel, Dhakal, Subesh, Ullah, Hayat, Agarwal, Anshul, Datta, Avishek
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-07-2021
Springer Nature B.V
Subjects:
Agricultural practices
Agriculture
Biomedical and Life Sciences
Cost control
Crop yield
Cultivation
Dry matter
Dry season
Drying
Farms
Field tests
Flooding
Grain
Grain cultivation
Irrigation water
Life Sciences
Nitrogen
Optimization
Original Article
Plant populations
Productivity
Rice
Seeding
Seeding rate
Synchronism
Synchronization
Water management
Water regimes
Wetting
Alternate wetting and drying
Wet direct seeding
Continuous flooding
Agronomic practices
Water productivity
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Summary:Adoption of appropriate agronomic practices, such as optimum seeding and nitrogen (N) rates, in synchronization with proper water management practice could help improve yield, water productivity and N use efficiency (NUE) of rice ( Oryza sativa L.). Field experiments were conducted at the research farm of the Asian Institute of Technology during the dry seasons (November–March) of 2017–2018 and 2018–2019 to evaluate the effects of seeding (S) (95 [S 95 ], 125 [S 125 ] and 155 [S 155 ] kg ha −1 ) and N (0 [N 0 ], 60 [N 60 ] and 120 [N 120 ] kg ha −1 ) rates under different water regimes (continuous flooding [CF] and safe alternate wetting and drying [AWD15]) on yield, water productivity and NUE of wet direct-seeded rice. Application of 120 kg N ha −1 (N 120 ) resulted in the highest grain yield and water productivity (by 76% and 78%, respectively, compared with N 0 ), which were statistically similar with N 60 . Less plant population in lower seeding rates (S 95 and S 125 ) provided better results in terms of vegetative and reproductive growth, grain yield and water productivity. Rice grown under AWD15 resulted in statistically similar grain yield with rice maintained under CF, but there was 40–44% more water savings depending on seeding rates and 68% higher water productivity in AWD15-treated plots. Improving sink capacity and dry matter accumulation is key to ensuring better grain yields even with reduced N and seeding rates under AWD15. A stronger relationship between grain yield and spikelet number panicle −1 as well as between shoot dry matter and spikelet number panicle −1 was observed under CF (r = 0.61 and r = 0.57, respectively) compared with AWD15 (r = 0.45 and r = 0.41, respectively). N 60 had significantly higher partial factor productivity (64.6) of applied N than N 120 (36.4). S 95 and S 125 resulted in a significant improvement in NUE compared with S 155 . This result suggests that desirable grain yield and water productivity as well as better NUE could be achieved by decreasing N rate from 120 to 60 kg ha −1 , and thus significant reduction in fertilizer input cost could be possible along with environmental benefits. In addition, decreasing seeding rate coupled with AWD15 is recommended to reduce the input cost and total water input to make the wet direct-seeded rice cultivation system more sustainable and profitable.
ISSN:1385-1314
1573-0867
DOI:10.1007/s10705-021-10153-6