Abstract
Since each greenhouse gas (GHG) has its own radiative capacity, all three gasses (CO2, CH4 and N2O) must be accounted for by calculating the net global warming potential (GWP) in a crop production system. To compare the impact of GHG fluxes from the rice growing and the fallow season on the annual gas fluxes, and their contribution to the GWP and carbon sequestration (CS) were evaluated. From May to April in Bibai (43°18′ N, 141°44′ E), in central Hokkaido, Japan, three rice paddy fields under actual management conditions were investigated to determine CS and the contribution of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) fluxes to GWP. Methane and N2O fluxes were measured by placing the chamber over the rice plants covering four hills and CO2 fluxes from rice plants root free space in paddy fields were taken as an indicator of soil microbial respiration (Rm) using the closed chamber method. Soil CS was calculated as the difference between net primary production (NPP) and loss of carbon (C) through Rm, emission of CH4 and harvest of crop C. Annual cumulative Rm ranged from 422 to 519 g C m−2 yr−1; which accounted for 54.7 to 55.5% of the rice growing season in particular. Annual cumulative CH4 emissions ranged from 75.5 to 116 g C m−2 yr−1 and this contribution occurred entirely during the rice growing period. Total cumulative N2O emissions ranged from 0.091 to 0.154 g N m−2 yr−1 and from 73.5 to 81.3% of the total N2O emissions recorded during the winter-fallow season. The CS ranged from −305 to −365 g C m−2 yr−1, suggesting that C input by NPP may not be compensate for the loss of soil C. The loss of C in the winter-fallow season was much higher (62 to 66%) than in the growing season. The annual net GWP from the investigated paddy fields ranged from 3823 to 5016 g CO2 equivalent m−2 yr−1. Annual GWPCH4 accounted for 71.9 to 86.1% of the annual net GWP predominantly from the rice growing period. These results indicate that CH4 dominated the net GWP of the rice paddy.
Highlights
Since the pre-industrial era, the concentration of global atmospheric carbon dioxide (CO2 ) has increased from 278 ppmv to 3905 ppmv in 2011
The carbon sequestration (CS) values ranged from −305 to −365 g C m−2 yr−1, suggesting that C obtained as a result of net primary production (NPP) was not enough to offset C losses from paddy soils by Rm, CH4 emission and C
Due to the impact of residue management followed by water management on C fluxes (CO2 -C and CH4 -C), the loss of C may not be compensated by NPP
Summary
Since the pre-industrial era (defined as 1750), the concentration of global atmospheric carbon dioxide (CO2 ) has increased from 278 ppmv to 3905 ppmv in 2011. Nitrous oxide emissions from agricultural fields, comprising approximately 5% of total organic anthropogenic GHG emissions [4], are primarily associated with applications of inorganic and organic nitrogen fertilizer in cultivated arable upland systems [5]. Studies have shown that a large amount of GHGs are released from paddy fields; likewise a significant amount of CO2 is stored by plant in paddy fields [11,12,13,14].
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