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简介:本研究通过收集国内已发表的文献中具有凋落物分解常数的数据,采用SPSS13.0软件综合分析中国森林凋落物分解速率的影响因素.结果发现:凋落物类型对凋落物分解速率有显著影响(P〈0.05),凋落叶氮含量与分解速率呈极显著正相关(P〈0.01).在同一样地的研究中,混合分解的凋落叶分解常数极显著高于单独分解的(P〈0.01).叶习性对凋落叶分解速率没有显著影响(P〉0.05),但在中国的温带地区则有显著影响(P〈0.05).在全国尺度上树种组成对凋落物分解速率没有显著影响(P〉0.05).凋落叶分解速率与经度、年均温和降水量成极显著正相关(P〈0.01),与纬度和海拔成极显著负相关(P〈0.01).凋落叶分解速率的Q10值为1.768.网袋孔径与土壤类型对凋落叶分解速率亦均有极显著影响(P〈0.01).
简介:二氧化碳、甲烷和氧化亚氮是3种重要的温室气体。水库是这些温室气体的重要排放源,排放途径多样,而且排放受诸多因素影响,其温室气体的排放量在时间和空间上存在差异。水库消落区是连接水陆生态系统能流、物流的枢纽,是温室气体产生的重要场所。通过分析国内外水库温室气体排放相关领域的研究成果,阐述了水库消落区、水库沉积物中温室气体的产生和排放特点;总结分析了水库温室气体的4个主要排放途径:水面自由扩散、气泡排放、水轮机和溢洪道、大坝下游河流排放;从季节变化、水面风速、水体pH、水温、水体含氧量、水位变化、水体中氮元素和磷元素浓度、库龄等角度,深入探讨了水库温室气体排放的影响因素;提出了未来在水库温室气体研究中需要加强的几方面内容。
简介:生物炭对土壤中多环芳烃(PAHs)环境行为的影响较大。通过批次实验,研究了不同温度(300℃、500℃和700℃)下制备的稻壳生物炭(BC)对3种土壤(草甸土、水稻土和黄壤)吸附菲的影响。结果表明,生物炭、土壤以及添加生物炭的土壤对菲的吸附数据都能用Freundlich模型较好地拟合(砰为0.9968~0.9765)。生物炭对菲的吸附容量(群值)随着制备温度的升高而增加。生物炭添加对土壤吸附菲的群值的影响程度跟生物炭的制备温度以及土壤有机质含量有关,700℃下制备的生物炭(700BC)对3种土壤吸附菲的群值都能显著提高;500℃下制备的生物炭(500BC)对有机质含量低的黄壤和水稻土的群值有显著提高,但对有机质含量高的草甸土提高有限;300℃下制备的生物炭(300BC)只能显著提高水稻土对菲吸附的群值。因此,在用生物炭修复PAHs污染土壤时,生物炭和土壤的性质都是需要考虑的重要因素。