Co-application of biochar and compost with decreased N fertilizer reduced annual ammonia emissions in wetland rice

Ferdous, Jannatul; Mumu, Nusrat Jahan; Hossain, Md. Belal; Hoque, Md. Anamul; Zaman, Mohammad; Müller, Christoph; Jahiruddin, M.; Bell, R.W.; Jahangir, M. M. R.

doi:10.3389/fsufs.2022.1067112

Cited by 7 publications

(1 citation statement)

References 52 publications

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“…Another portion of the soil was air-dried at room temperature (~25 °C) in the shade for two weeks and then processed (2 mm sieved) for analysis of SOC and total N (TN) using the wet oxidation method and Kjeldahl method, respectively (Jahangir et al, 2022). The values and corresponding sources used for the crops in this area are available in Begum et al (2022), Jahangir et al, (2022) and Ferdous et al (2023). To measure grain and residue biomass production, a 4 m 2 area was chosen at random in the plot area just before harvest.…”

Section: Soil and Biomass Sampling And Analysismentioning

confidence: 99%

Carbon footprint and greenhouse gas emissions from rice based agricultural systems calculated with a co-designed carbon footprint calculation tool

Jahangir,

Aguilera,

Ferdous

et al. 2023

Preprint

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Abstract. There are many cropping systems followed in Floodplain soils for enhancing cropping intensity for increasing crop production, but greenhouse gas (GHG) emissions balances of agricultural systems are rarely reported. To estimate the carbon (C) footprints of agricultural products a co-designed C footprint calculation tool with a life cycle assessment approach was used in major cropping systems in Bangladesh: rice-rice-rice (R-R-R/boro-aus-aman), rice-fallow-rice (R-F-R/boro-fallow-aman), maize-fallow-rice (M-F-R), wheat-mungbean-rice (W-M-R), and potato-rice-fallow (P-R-F). GHG emissions were estimated using the tool along with the field measurements. It was found that rice-based cropping pattern with dryland crops had higher nitrous oxide (N2O) emissions (3.98 in maize, 3.89 in potato and 0.72 kg N2O-N ha−1 in mungbean) than sole rice-based (0.73 in boro, 0.57 in aus and 1.94 kg N2O-N ha−1 in aman) cropping systems but methane (CH4) emissions were higher in sole rice-based patterns than dryland crops. Methane contributed to about 50–80 % of total GHG emissions from rice cultivation due to waterlogging conditions throughout the season. In R-R-R and R-F-R cropping patterns, the only ones including boro rice, had the highest total C footprint with 26.3 and 19.5 Mg CO2e ha−1, respectively while the P-F-R and M-F-R had the lowest C footprint with 13 Mg CO2e ha−1. Changes in soil organic C generally had a minor influence on C footprints in the studied systems, and only boro and aus from R-F-R and R-R-R patterns were relatively more suitable for reducing C footprint as they sequestered C in soil. Measured CH4 and N2O emissions agreed well with IPCC tier 1 estimates, but they were only available for boro, maize and wheat so further study is required for validation and suggesting suitable GHG mitigation strategies from agricultural fields.

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