土壤有机质和外源有机物对甲烷产生的影响

对土壤有机质含量及组分、外源有机物和根系分泌对甲烷产生的影响作了综述。土壤产甲烷量和甲烷排放量随有机质含量增加而提高，与土壤中易矿化有机碳或沸水浸提有机碳含量呈显著相关。外源有机碳加入促进了土壤排放甲，刺激效果与外源有机碳的用量和组成有关。还原力强的有机物如纤维素和半纤维素较还原力弱的有机物如类脂和多糖能够产生更多的甲烷。甲醇、甲基化氨基酸等无其它微生物竞争利用的有机物能被产甲烷菌更多地转化成甲烷。植物根系分泌物也促进甲烷的产生，促进作用大小与植物种类及分泌物的数量和质量有关。外源有机物通过3种方式促进土壤甲烷产生；提高土壤的甲烷底物供应量，降低土壤氧化还原电位，刺激土壤原有有机碳的转化。

Effects of Soil Organic Matter and Exogenous Organic Materials on Methane Production in and Emission from Wetlands

The CH 4 concentration in the atmosphere is increasing continuously, with possibly profound consequences for future global climate. Wetlands, including rice paddy fields and mires, contribute between 15 and 45% of global CH 4 emissions. CH 4 emissions from wetlands show a large variation, which can't so far clearly be predicted by environmental and soil variables. This limits the accuracy of estimates of both current and future global CH 4 emission. CH 4 production is a microbiological process, which takes place under anaerobic conditions with supplies of organic substrates. Once anaerobiosis is established, soil organic matter is generally considered as a key limited factor for CH 4 production. The paper reviews the research progresses of the effects of soil organic matter and exogenous organic materials inputting into wetlands on CH 4 production. Under anaerobic conditions, both native organic matter and exogenous organic materials in wetlands are decomposed biologically into simple organic matters and CO 2 via a series of reactions. Methane is produced as a final step of anaerobic degradation of organic matters, mediated by methanogens. Methanogenic bacteria use a limited number of substrates, of which acetate, CO 2, and hydrogen are the most important ones. CH 4 production in and emission from wetlands are not closely related with total organic materials in soils, but significantly with labile organic matter and the organic matter that could be extracted by water under boiling condition. That is to say that CH 4 production and emission in the absence of oxygen are controlled by strongly reducible rather than weakly reducible organic materials. A method that efficiently discriminates the strongly reducible organic carbon from soil organic matter urgently needs to be developed in order to accurately predict the CH 4 production potential in soils. Addition of organic materials to soils usually occurs in most rice-based agroecosystems for improving soil fertility. The stimulation effect of exogenous organic materials on CH 4 emissions relies on their quantity and composition. Strongly reducible organic materials such as cellulose and hemicelluloses can produce more CH 4 than the weakly reducible ones such as polysaccharides and lipoid. Methanol and methylic amino acids can be transformed into CH 4 even more effectively. Plant exudates are also able to stimulate CH 4 production, lying on plant varieties, the quantity and composition of exudates. The mechanisms for stimulation effect of exogenous organic materials on CH 4 production are to provide substrates for CH 4 production, lower soil redox potential, and accelerate decomposition of native organic carbon in soils.