Methane Emissions of Rice Increased by Elevated Carbon Dioxide and Temperature

Abstract

Methane (CH₄) effluxes by paddy-culture rice (Oryza sativa L.) contribute about 16% of the total anthropogenic emissions. Since radiative forcing of CH₄ at current atmospheric concentrations is 21 times greater on a per mole basis than that of carbon dioxide (CO₂), it is imperative that the impact of global change on rice CH₄ emissions be evaluated. Rice (cv. IR72) was planted in sunlit, closed-circulation, controlled-environment chambers in which CH₄ efflux densities were measured daily. The CO₂ concentration was maintained at either 330 or 660 μmol mol⁻¹ Air temperatures were controlled to daily maxima and minima of 32/23, 35/26, and 38/29°C at each CO₂ treatment. Emissions of CH₄ each day were determined during a 4-h period after venting and resealing the chambers at 0800 h. Diurnal CH₄ effluxes on 77, 98, and 119 d after planting (DAP) were obtained similarly at 4-h intervals. Emissions over four-plant hills and over flooded bare soil were measured at 53, 63, and 100 DAP. Emissions were negligible before 40 DAP. Thereafter, emissions were observed first in high-CO₂, high-temperature treatments and reached a sustained maximum efflux density of about 7 mg m⁻² h⁻¹ (0.17 g m⁻² d⁻¹) near the end of the growing season. Total seasonal CH₄ emission was fourfold greater for high-CO₂, high-temperature treatments than for the low-CO₂, low-temperature treatment, probably due to more root sloughing or exudates, since about sixfold more acetate was found in the soil at 71 DAP. Both rising CO₂ and increasing temperatures could lead to a positive feedback on global warming by increasing the emissions of CH₄ from rice. Copyright © 2003. American Society of Agronomy, Crop Science Society of America, Soil Science Society . ASA, CSSA, SSSA