Abstract
A major portion (60–90%) of the methane (CH4) emitted from rice fields to the atmosphere is transported through the aerenchyma of the rice plants. However, a rapid and accurate method to study the CH4 transport capacity (MTC) of rice plants is not available. We developed a gas sampling and analytical device based on a closed two-compartment chamber technique and analyzed the enrichment of the CH4 mixing ratio inside the shoot compartment of cylindrical cuvettes enclosing individual rice plants under ambient conditions. The computer-controlled analytical system consists of a gas chromatograph (GC) and a pressure-controlled autosampler for eight cuvettes (seven for plants and one for CH4-calibration gas). The system automates closure and opening of plant cuvettes using pneumatic pressure, air sample collection and injection into the GC, and CH4 analysis. It minimizes sources of error during air sampling by continuously mixing headspace air of each cuvette, maintaining pressure and composition of the headspace inside the cuvettes, purging the dead volumes between the sampler induction tube and GC, and running a reference CH4-calibration gas sample in each cycle. Tests showed that the automated system is a useful tool for accurate sampling of headspace air of cylindrical cuvettes enclosing individual rice plants and enables rapid and accurate fully automated analysis of CH4 in the headspace air samples. A linear relationship was obtained between CH4 transported by rice plants of two cultivars (IR72, a high-yielding dwarf, and Dular, a traditional tall cultivar) and concentration of CH4 up to 7,500 ppm used for purging the nutrient culture solution surrounding the roots in the root compartment of the chamber. Further increase in CH4 emission by shoots was not observed at 10,000 ppm CH4 concentration in the root compartment of the chamber. The MTC of IR72 was measured at six development stages; it was lowest at seedling stage, increasing gradually until panicle initiation. There was no further change at flowering, but a marked decrease at maturity was noted. These results suggest that the plants have 45–246% greater potential to transport CH4 than the highest CH4 emission rates reported under field conditions, and plants would not emit CH4 at early growth and at a reduced rate close to ripening.
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References
Achtnich C, Bak F & Conrad R (1995) Competition for electron donors among nitrate reducers, ferric iron reducers, sulfate producers and methanogens in anoxic paddy soil. Biol Fertil Soils 19:65–72
Bartolome VI, Casumpang RM, Ynalvez MAH, Olea AB & McLaren CG (1999) IRRISTAT for Windows-statistical software for agricultural research. Biometrics, International Rice Research Institute, Makati City, Philippines
Blake DR & Rowland FS (1988) Continuing worldwide increase in tropospheric methane, 1978 to 1987. Science 239:1129–1131
Buendia LV, Neue HU, Wassmann R, Lantin RS, Javellana AM, Yuchang X, Makarim AK, Corton TM & Charoensilp N (1997) Understanding the nature of methane emission from rice ecosystems as basis of mitigation strategies. Appl Energy 56:433–444
Butterbach-Bahl K, Papen H & Rennenberg H (1997) Impact of gas transport through rice cultivars on methane emission from paddy fields. Plant Cell Environ 20: 1175–1183
Cicerone RJ & Shetter JD (1981) Sources of atmospheric methane: measurements in rice paddies and a discussion. J Geophys Res 86:7203–7209
Cochran WG & Cox GM (1950) Experimental Designs. John Wiley and Sons, Inc, New York
Denier van der Gon HAC & Neue HU (1995) Influence of organic matter incorporation on the methane emission from a wetland rice field. Global Biogeochem Cycles 9: 11–22
Dlugokencky E, Steele P, Lang PM, Tans P & Masaire K (1994) The growth rate and distribution of atmospheric methane. J Geophys Res 99:17021–17043
Etheridge DM, Pearman GI & Fraser PJ (1992) Changes in tropospheric methane between 1841 and 1978 from a high accumulation rate Antarctic ice core. Tellus 44:282–294
Holzapfel-Pschorn A, Conrad R & Seiler W (1986) Effects of vegetation on the emission of methane from submerged paddy soil. Plant Soil 92:223–391
Holzapfel-Pschorn A & Seiler W (1986) Methane emission during a cultivation period from an Italian rice paddy. J Geophy Res 91:11803–11814
IPCC – Intergovernmental Panel on Climate Change (1992) Climate Change: The Supplementary Report to the IPCC Scientific Assessment, Houghton JT, Callander BA & Varney SK (eds) IPCC, Cambridge University Press, Cambridge
IPCC – Intergovernmental Panel on Climate Change (1995) Climate Change: The Science of Climate Change, Houghton JT, Meira Filho LG, Callander BA, Harris N, Kattenberg A, Maskell K (eds) IPCC, Cambridge University Press, Cambridge
Neue HU & Sass R (1998) The budget of methane from rice fields. IGAC tivities 17:3–11
Nouchi I, Mariko S & Aoki K (1990) Mechanism of methane transport from the rhizosphere to the atmosphere through rice plants. Plant Physiol 94:59–66
Nouchi I & Mariko S (1993) Mechanism of methane transport by rice plants. In: Oremland RS (ed). Biogeochemistry of Global Change, Radiatively Active Trace Gases, pp 336–352, Chapman Hall, New York
Nouchi I (1994) Mechanisms of methane transport through rice plants. In: Minami K, Mosier A, Sass R (eds) CH4 and N2O: Global Emissions and Controls from Rice Fields and Other Agricultural and Industrial Sources, pp 87–104, National Institute of Agro-Environmental Sciences, Tsukuba, Japan..
Raynaud D, Jouzel J, Barnola JM, Chappellaz J, Delmas RJ & Lorius C (1993) The ice record of greenhouse gases. Science 259:926–933
Schütz H, Seiler W & Conrad R (1989) Processes involved in formation and emission of methane in rice paddies. Biogeochem 7:33–53
Wassmann R & Aulakh MS (2000) The role of rice plants in regulating mechanisms of methane emissions: A review. Biol Fertil Soils 31:20–29
Wassmann R, Neue HU, Alberto MCR, Lantin RS, Bueno C, Llenaresas D, Arah JRM, Papen H, Seiler W &Rennenberg H (1996) Fluxes and pools of methane in wetland rice soils with varying organic inputs. Environ Monitor Assess 42:163–173
Wassmann R, Buendia LV, Lantin RS, Bueno CS, Lubigan LA, Umali A, Nocon NN, Javellana AM & Neue HU (2000) Mechanisms of crop management impact on methane emissions from rice fields in Los Baños, Philippines. Nutr Cycling Agroecosyst, this issue
Westermann P & Ahring BK (1987) Dynamics of methane production, sulfate reduction and denitrification in a permanently waterlogged alder swamp. Appl Environ Microbiol 53:2554–2559
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Aulakh, M., Bodenbender, J., Wassmann, R. et al. Methane Transport Capacity of Rice Plants. I. Influence of Methane Concentration and Growth Stage Analyzed with an Automated Measuring System. Nutrient Cycling in Agroecosystems 58, 357–366 (2000). https://doi.org/10.1023/A:1009831712602
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DOI: https://doi.org/10.1023/A:1009831712602