雷竹覆盖物分解速率及其硅含量的变化

以冬季地表覆盖增温为核心的雷竹早产高效栽培技术被广泛应用于我国亚热带地区的雷竹(Phyllostachys praecox)产区。为探明雷竹覆盖物（稻草和竹叶）的分解速率及在分解残余物中硅含量的年动态变化规律，在浙江临安市雷竹主产区采用分解管法进行了覆盖物分解试验。试验结果表明，稻草、竹叶的月平均分解速率分别为8.5 %和11.9 %，在1a内分别分解了67.5 %和79.3 %。在1年的分解过程中，稻草和竹叶C含量随时间的推移而下降，而N含量则随时间的推移而增加，两者的C/N比总体都呈现下降的趋势，但在试验初期前者的下降幅度显著大于后者。稻草、竹叶覆盖残余物中的Si含量随着分解时间的增加而增加，并都在12月达到最大值81.8 g?kg-1和80.0 g?kg-1。稻草、竹叶的分解残余物中硅含量与铝含量或铁含量之间均呈极显著正相关（p<0.01），但与磷含量无显著相关性(p>0.05)。

Decomposition rate and silicon dynamic of mulching residue under Phyllostachys praecox stands

Phytolith-occluded organic carbon (PhytOC) in the soils is an important long-term carbon pool in terrestrial and plays an important role in regulation of global carbon cycle and mitigation of global climate warming. Intensive management technique including winter mulching has been widely used in the cultivation area of Phyllostachys praecox in the subtropical regions of China. The decomposition of mulching materials with high silicon content (bamboo leaves and rice straw) provides large amounts of silicon for Phyllostachys praecox ecosystem, thus affecting the formation of PhytOC in the ecosystem. To ascertain decomposition rate of mulching materials and silicon dynamic change of mulching residue on the land of Phyllostachys praecox stand, a decomposition experiment of mulching materials was conducted in the main typical production area of Phyllostachys praecox of Lin'an city, Zhejiang province by using decomposition tube method. The experiment results showed that the decomposition of rice straw and bamboo leaves mainly occurred between March and October.The decomposition peak of rice straw and bamboo leaves happened in July and August and the decomposition rates were 16.3% and 19.1%, respectively. The decomposition half-life of rice straw and bamboo leaves was 228 d and 166 d, respectively. Rice straw and bamboo leaves were decomposed by 67.5% and 79.3% during one year decay, respectively. During one-year decomposition process, C contents in rice straw and bamboo leaves decreased with time,whereas N contents in those increased with time. Carbon contents in bamboo leaves and rice straw and were decreased by 14.8% and 15.3%, respectively. Nitrogen contents in bamboo leaves and rice straw were increased by 15.8 and 174.4%, respectively. The ratios of C/N in bamboo leaves and rice straw were a decrease tendency with time. Decline ranges of the C/N ratios in bamboo leaves and rice straw were 26.4% and 67.5%, respectively. During the experiment period, Si contents in the mulching residues of rice straw and bamboo leaves increased with time. The maximum Si contents in the mulching residues occurred in December. Silicon contents in the mulching residues of rice straw and bamboo leaves were 81.8g/kg and 80.0 g/kg at the end of the experiment, respectively, which were 3.9 and 3.1 times greater than before the decomposition. The contents of Al and Fe in the mulching residues of rice straw and bamboo leaves increased with time. The contents of Al and Fe in the mulching residues of rice straw and bamboo leaves ranged 0.2-8.4 g/kg and 0.3-5.4 g/kg, respectively. The changes trends of P contents in the mulching residues of rice straw and bamboo leaves were the two-peaked curves. The P content in the mulching residues of rice straw ranged from 0.7 g/kg to 1.4 g/kg. The P contents in the mulching residues of bamboo leaves ranged from 1.0 g/kg to 1.7 g/kg. Silicon contents in the mulching residues of rice straw and bamboo leaves was positively correlated with Al or Fe contents (P < 0.01), but where was no relationship between Si contents and P contents (P > 0.05).