Abstract
Vertical profiles were measured in soil cores taken from flooded rice fields in the Po valley during July and August 1990. Methane concentrations generally increased with depth and reached maximum values of 150–500 μM in 5–13 cm depth. However, the shape of the profiles was very different when studying different soil cores. The CH4 content of gas bubbles showed a similar variability which apparently was due to spatial rather than temporal inhomogeneities. Similar inhomogeneities were observed in the vertical profiles of acetate, propionate, lactate, and formate which showed maximum values of 1500, 66, 135, and 153, μM, respectively. However, maxima and minima of the vertical profiles of the different substates usually coincided in one particular soil core. Large inhomogeneities in the vertical profiles were also observed for the rates of total CH4 production, however, the percentage contribution of H2/CO2 to CH4 production was relatively homogeneous at 24 ± 7% (SD). Similarly, the H2 content of gas bubbles was relatively constant at 93.3 ± 9.6 ppmv when randomly sampled in the rice field at different times of the day. A small contribution (6%) of H2/CO2 to acetate production was also observed. Vertical profiles of the respiratory index (RI) for [2-14C] acetate showed that acetate was predominantly degraded by methanogenesis in 5–11 cm depth, but by respiration in the surface soil (3 cm depth) and in soil layers below 13–16 cm depth which coincided with a transition of the colour (grey to reddish) and the physical characteristics (porosity, density) of the soil. The observations indicate that the microbial community which degrades organic matter to CH4 is in itself relatively homogenous, but operates at highly variable rates within the soil structure.
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References
Aselmann I & Crutzen PJ (1989) Global distribution of natural freshwater wetlands and rice paddies, their net primary productivity, seasonality and possible methane emissions. J. Atmos. Chem. 8: 307–358
Bak F & Pfennig N (1991) Sulfate-reducing bacteria in littoral sediment of Lake Constance. FEMS Microbiol. Ecol. 85: 43–52
Chanton JP & Dacey JW (1991) Effects of vegetation on methane flux, reservoirs, and carbon isotopic composition. In: Rogers JE & Whitman WB (Eds) Trace Gas Emissions by Plants (pp 65–92). Academic Press, New York
Cicerone RJ & Shetter JD (1981) Sources of atmospheric methane: measurements in rice paddies and a discussion. J. Geophys. Res. 86: 7203–7209
Conrad R (1989) Control of methane production in terrestrial ecosystems. In: Andreae MO & Schimel DS 58(Eds) Exchange of Trace Gases between Terrestrial Ecosystems and the Atmosphere. Dahlem Konferenzen (pp 39–58). Wiley, Chichester
Conrad R (1993a) Mechanisms controlling methane emission from wetland rice fields. In: Oremland RS (Ed) The Biogeochemistry of Global Change: Radiative Trace Gases (in press). Chapman & Hall, New York
Conrad R (1993b) Anaerobic hydrogen metabolism in aquatic sediments. In: Adams DD, Seitzinger SP & Crill PM (Eds) Cycling of Reduced Gases in the Hydrosphere (in press). Schweizerbart'sche Verlagsbuchhandlung, Stuttgart
Conrad R & Babbel M (1989) Effect of dilution on methanogenesis, hydrogen turnover and interspecies hydrogen transfer in anoxic paddy soil. FEMS Microbiol. Ecol. 62: 21–27
Conrad R, Bak F, Seitz HJ, Thebrath B, Mayer HP & Schütz H (1989a) Hydrogen turnover by psychotrophic homoacetogenic and mesophilic methanogenic bacteria in anoxic paddy soil and lake sediment. FEMS Microbiol. Ecol. 62: 285–294
Conrad R, Mayer HP & Wüst M. (1989b) Temporal change of gas metabolism by hydrogensyntrophic methanogenic bacterial associations in anoxic paddy soil. FEMS Microbiol. Ecol. 62: 265–274
Conrad R & Rothfuss F (1991) Methane oxidation in the soil surface layer of a flooded rice field and the effect of ammonium. Biol. Fertil. Soils 12: 28–32
Conrad R & Schütz H (1988) Methods of studying methanogenic bacteria and methanogenic activities in aquatic environments. In: Austin B (Ed) Methods in Aquatic Bacteriology (pp 301–343). Wiley, Chichester
Conrad R, Schütz H & Babbel M (1987) Temperature limitation of hydrogen turnover and methanogenesis in anoxic paddy soil. FEMS Microbiol. Ecol. 45: 281–289
Crozier TE & Yamamoto S (1974) Solubility of hydrogen in water, seawater, and NaCl solutions. J. Chem. Engineer. Data 19: 242–244
Dolfing J (1988) Acetogenesis. In: Zehnder AJB (Ed) Biology of Anaerobic Microorganisms (pp 417–468). Wiley, New York
Frenzel P, Thebrath B & Conrad R (1990) Oxidation of methane in the oxic surface layer of a deep lake sediment (Lake Constance). FEMS Microbiol. Ecol. 73: 149–158
Frenzel P, Rothfuss F & Conrad R (1992) Oxygen profiles and methane turnover in a flooded rice microcosm. Biol. Fertil. Soils 14: 84–89
Gottschalk G (1986) Microbial Metabolism, 2nd edition. Springer, New York
Holzapfel-Pschorn A, Conrad R & Seiler W (1985) Production, oxidation and emission of methane in rice paddies. FEMS Microbiol. Ecol. 31: 343–351
Holzapfel-Pschorn A & Seiler W (1986) Methane emission during a cultivation period from an Italian rice paddy. J. Geophys. Res. 91: 11803–11814
Khalil MAK, Rasmussen RA, Wang MX & Ren L (1991) Methane emissions from rice fields in China. Environ. Sci. Technol. 25: 979–981
Krumböck M & Conrad R (1991) Metabolism of position-labelled glucose in anoxic methanogenic paddy soil and lake sediment. FEMS Microbiol. Ecol. 85: 247–256
Lindau CW, Patrick WH, DeLaune RD & Reddy KR (1990) Rate of accumulation and emission of N2, N2O and CH4 from a flooded rice soil. Plant and Soil 129: 269–276
Médard L et.al. (1976) L'Air Liquide, Gas Encyclopedia. Elsevier, Amsterdam
Sass RL, Fisher FM, Harcombe PA & Turner FT (1990) Methane production and emission in a Texas rice field. Global Biogeochem. Cycles 4: 47–68
Sass RL, Risher FM, Turner FT & Jund MF (1991) Methane emission from rice fields as influenced by solar radiation, temperature, and straw incorporation. Global Biogeochem. Cycles 5: 335–350
Schauer NL & Ferry JG (1980) Metabolism of formate in Methanobacterium formicicum. J. Bacteriol. 42: 800–807
Schink B (1992) Syntrophism among prokaryotes. In: Balows A, Trüper HG, Dworkin M, Harder W & Schleifer KH (Eds) The Prokaryotes, 2nd ed, vol. 1 (pp 276–299). Springer, New York
Schütz H, Conrad R, Goodwin S & Seiler W (1988) Emission of hydrogen from deep and shallow freshwater environments. Biogeochem. 5: 295–311
Schütz H, Holzapfel-Pschorn A, Conrad R, Rennenberg H & Seiler W (1989a) A 3-year continuous record on the influence of daytime, season, and fertilizer treatment on methane emission rates from an Italian rice paddy. J. Geophys. Res. 94: 16405–16416
Schütz H, Seiler W & Conrad R (1989b) Processes involved in formation and emission of methane in rice paddies. Biogeochem. 7: 33–53
Seiler W, Holzapfel-Pschorn A, Conrad R & Scharffe D (1984) Methane emission from rice paddies. J. Atmos. Chem. 1: 241–268
Thebrath B, Mayer HP & Conrad R (1992) Bicarbonate-dependent production and methanogenic consumption of acetate in anoxic paddy soil. FEMS Microbiol. Ecol. 86: 295–302
Thebrath B, Rothfuss F, Whiticar MJ & Conrad R (1993) Methane production in littoral sediment of Lake Constance. FEMS Microbiol. Ecol., in press.
Widdel F (1986) Growth of methanogenic bacteria in pure culture with 2-propanol and other alcohols as hydrogen donors. Appl. Environ. Microbiol. 51: 1056–1062.
Yagi K & Minami K (1991) Emission and production of methane in the paddy fields of Japan. Jap. Agr. Res. Quart. 25: 165–171
Yamane I & Sato K (1964) Decomposition of glucose and gas formation in flooded soil. Soil Sci. Plant Nutr. 10: 35–41
Zehnder AJB (1978) Ecology of methane formation. In: Mitchell R (Ed) Water Pollution Microbiology, vol. 2 (pp 349–376). Wiley, New York
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Rothfuss, F., Conrad, R. Vertical profiles of CH4 concentrations, dissolved substrates and processes involved in CH4 production in a flooded Italian rice field. Biogeochemistry 18, 137–152 (1992). https://doi.org/10.1007/BF00003274
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DOI: https://doi.org/10.1007/BF00003274