The effective mitigation of greenhouse gas emissions from rice paddies without compromising yield by early-season drainage

TL;DR

This study demonstrates that early-season drainage combined with mid-season drainage significantly reduces greenhouse gas emissions from rice paddies without harming crop yield, offering a promising mitigation strategy.

Contribution

It introduces and tests specific early-season drainage regimes, showing their effectiveness in reducing methane emissions while maintaining rice yields.

Findings

Early-season drainage reduces methane emissions by up to 90%.

Combining ED with MD significantly lowers yield-scaled global warming potential.

Nitrous oxide emissions remain unaffected by drainage regimes.

Abstract

Global rice production systems face two opposing challenges: the need to increase production to accommodate the world's growing population while simultaneously reducing greenhouse gas (GHG) emissions. Adaptations to drainage regimes are one of the most promising options for methane mitigation in rice production. Whereas several studies have focused on mid-season drainage (MD) to mitigate GHG emissions, early-season drainage (ED) varying in timing and duration has not been extensively studied. However, such ED periods could potentially be very effective since initial available Carbon levels (and thereby the potential for methanogenesis) can be very high in paddy systems with rice straw incorporation. This study tested the effectiveness of seven drainage regimes varying in their timing and duration (combinations of ED and MD) to mitigate methane (CH4) and nitrous oxide (N2O) emissions in a 101-day growth chamber experiment. Emissions were considerably reduced by early-season drainage compared to both conventional continuous flooding (CF) and the MD drainage regime. The results suggest that ED + MD drainage may have the potential to reduce methane emissions and yield-scaled global warming potential by 85 to 90% compared to CF and by 75 to 77% compared to MD only. A combination of (short or long) ED drainage and one MD drainage episode was found to be the most effective in mitigating methane emissions without negatively affecting yield. In particular, compared with CF, the long early-season drainage treatments LE + SM and LE + LM significantly decreased yield scaled global warming potential by 85% and 87% respectively. This was associated with carbon being stabilised early in the season, thereby reducing available carbon for methanogenesis. Overall nitrous oxide emissions were small and not significantly affected by ED.