Seasonal nitrous oxide emissions outweigh the effect of higher nitrogen rate in flooded triple rice systems

Seasonal nitrous oxide emissions outweigh the effect of higher nitrogen rate in flooded triple rice systems

Intensive rice cultivation with multiple aeration in both irrigated and rainfed farming leads to increased nitrous oxide (N2O) emissions. However, the spatio-temporal variations in N2O emissions has been largely neglected in the policy guidelines of seasonal rice cultivation. N2O emissions were quan...

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Veröffentlicht in:The Science of the total environment 2025-01, Vol.958, p.177887, Article 177887
Hauptverfasser: Jahangir, M.M.R., Shimo, F.J., Sakib, M., Ferdous, J., Riza, I.J., Sarker, P., Rahman, M.S., Zaman, M., Müller, C.
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Sprache:eng
Schlagworte:
Agriculture - methods
Air Pollutants - analysis
Bangladesh
Emission factors
Environmental Monitoring
Fertilizers - analysis
Floods
N rate
N2O emissions
Nitrogen - analysis
Nitrous Oxide - analysis
Oryza
Rice
Seasons
Temperature
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container_issue
container_start_page 177887
container_title The Science of the total environment
container_volume 958
creator Jahangir, M.M.R.
Shimo, F.J.
Sakib, M.
Ferdous, J.
Riza, I.J.
Sarker, P.
Rahman, M.S.
Zaman, M.
Müller, C.
description Intensive rice cultivation with multiple aeration in both irrigated and rainfed farming leads to increased nitrous oxide (N2O) emissions. However, the spatio-temporal variations in N2O emissions has been largely neglected in the policy guidelines of seasonal rice cultivation. N2O emissions were quantified in two rice regions in Bangladesh: Bogura and Cumilla in annual triple rice systems for two consecutive years. The treatments were two residue levels (NR, no residue and CR, crop was cut at 30 cm height); and four nitrogen (N) rates: control (no N), farmers' practice (FP), current recommended N rate (RD) and 125 % of RD, 1.25RD. The yield target and N application rate was different for the pre-monsoon rice (T. Aus), monsoon (T. Aman) and winter rice (Boro). The N2O emissions within the season increased with the N application rate. Despite the different N rates, N2O emissions were similar between seasons, suggesting that the estimation of N2O emission factors (EFs) needs to be disintegrated into the different seasons in multiple rice systems. Integration of crop residues coupled with RD of N fertilizer (CR-RD) increased N2O emissions over the NR with the same N rate (NR-RD). Mean N2O emissions ranged from 0.68 to 0.88 kg N ha−1 in Boro, 0.75 to 0.82 kg N ha−1 in T. Aus and 0.69 to 0.77 in T. Aman, indicating that even the lower N rate in the warmer seasons can emit similar N2O to the cooler season resulting in higher EFs. The N2O EFs, being higher in warmer seasons, ranged from 0.0039 to 0.0074, was slightly above the IPCC default EF (0.0033 for flooded and 0.0050 for intermittent draingage), but still within the global rice EF range. While crop residue increased rice N2O emissions, its integration with optimum N rates will minimize the climate impacts of rice through reduced N2O emissions. [Display omitted] •Crop residue integration with N rates enhances N2O emissions.•Seasonal influence on N2O emissions is more pronounced than N rate.•Low N input summer rice-N2O emissions compares with the high N input winter rice.•Rainfed rice has higher N2O emissions due to fluctuating soil moisture regimes.•Disintegration of N2O emissions factors into season improve rice N2O estimation.
doi_str_mv 10.1016/j.scitotenv.2024.177887
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However, the spatio-temporal variations in N2O emissions has been largely neglected in the policy guidelines of seasonal rice cultivation. N2O emissions were quantified in two rice regions in Bangladesh: Bogura and Cumilla in annual triple rice systems for two consecutive years. The treatments were two residue levels (NR, no residue and CR, crop was cut at 30 cm height); and four nitrogen (N) rates: control (no N), farmers' practice (FP), current recommended N rate (RD) and 125 % of RD, 1.25RD. The yield target and N application rate was different for the pre-monsoon rice (T. Aus), monsoon (T. Aman) and winter rice (Boro). The N2O emissions within the season increased with the N application rate. Despite the different N rates, N2O emissions were similar between seasons, suggesting that the estimation of N2O emission factors (EFs) needs to be disintegrated into the different seasons in multiple rice systems. Integration of crop residues coupled with RD of N fertilizer (CR-RD) increased N2O emissions over the NR with the same N rate (NR-RD). Mean N2O emissions ranged from 0.68 to 0.88 kg N ha−1 in Boro, 0.75 to 0.82 kg N ha−1 in T. Aus and 0.69 to 0.77 in T. Aman, indicating that even the lower N rate in the warmer seasons can emit similar N2O to the cooler season resulting in higher EFs. The N2O EFs, being higher in warmer seasons, ranged from 0.0039 to 0.0074, was slightly above the IPCC default EF (0.0033 for flooded and 0.0050 for intermittent draingage), but still within the global rice EF range. While crop residue increased rice N2O emissions, its integration with optimum N rates will minimize the climate impacts of rice through reduced N2O emissions. 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Integration of crop residues coupled with RD of N fertilizer (CR-RD) increased N2O emissions over the NR with the same N rate (NR-RD). Mean N2O emissions ranged from 0.68 to 0.88 kg N ha−1 in Boro, 0.75 to 0.82 kg N ha−1 in T. Aus and 0.69 to 0.77 in T. Aman, indicating that even the lower N rate in the warmer seasons can emit similar N2O to the cooler season resulting in higher EFs. The N2O EFs, being higher in warmer seasons, ranged from 0.0039 to 0.0074, was slightly above the IPCC default EF (0.0033 for flooded and 0.0050 for intermittent draingage), but still within the global rice EF range. While crop residue increased rice N2O emissions, its integration with optimum N rates will minimize the climate impacts of rice through reduced N2O emissions. 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However, the spatio-temporal variations in N2O emissions has been largely neglected in the policy guidelines of seasonal rice cultivation. N2O emissions were quantified in two rice regions in Bangladesh: Bogura and Cumilla in annual triple rice systems for two consecutive years. The treatments were two residue levels (NR, no residue and CR, crop was cut at 30 cm height); and four nitrogen (N) rates: control (no N), farmers' practice (FP), current recommended N rate (RD) and 125 % of RD, 1.25RD. The yield target and N application rate was different for the pre-monsoon rice (T. Aus), monsoon (T. Aman) and winter rice (Boro). The N2O emissions within the season increased with the N application rate. Despite the different N rates, N2O emissions were similar between seasons, suggesting that the estimation of N2O emission factors (EFs) needs to be disintegrated into the different seasons in multiple rice systems. Integration of crop residues coupled with RD of N fertilizer (CR-RD) increased N2O emissions over the NR with the same N rate (NR-RD). Mean N2O emissions ranged from 0.68 to 0.88 kg N ha−1 in Boro, 0.75 to 0.82 kg N ha−1 in T. Aus and 0.69 to 0.77 in T. Aman, indicating that even the lower N rate in the warmer seasons can emit similar N2O to the cooler season resulting in higher EFs. The N2O EFs, being higher in warmer seasons, ranged from 0.0039 to 0.0074, was slightly above the IPCC default EF (0.0033 for flooded and 0.0050 for intermittent draingage), but still within the global rice EF range. While crop residue increased rice N2O emissions, its integration with optimum N rates will minimize the climate impacts of rice through reduced N2O emissions. [Display omitted] •Crop residue integration with N rates enhances N2O emissions.•Seasonal influence on N2O emissions is more pronounced than N rate.•Low N input summer rice-N2O emissions compares with the high N input winter rice.•Rainfed rice has higher N2O emissions due to fluctuating soil moisture regimes.•Disintegration of N2O emissions factors into season improve rice N2O estimation.</abstract><cop>Netherlands</cop><pub>Elsevier B.V</pub><pmid>39644629</pmid><doi>10.1016/j.scitotenv.2024.177887</doi></addata></record>
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source MEDLINE; Elsevier ScienceDirect Journals
subjects Agriculture - methods
Air Pollutants - analysis
Bangladesh
Emission factors
Environmental Monitoring
Fertilizers - analysis
Floods
N rate
N2O emissions
Nitrogen - analysis
Nitrous Oxide - analysis
Oryza
Rice
Seasons
Temperature
title Seasonal nitrous oxide emissions outweigh the effect of higher nitrogen rate in flooded triple rice systems
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