松嫩盐碱退化草地羊草叶氮、磷化学计量与土壤因子关系研究被引量：8

Leaf N and P Stoichiometry of Leymus chinensis in Relation to Soil Properties in Saline-alkali Degraded Grassland

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摘要顶级群落建群种的N、P化学计量特征对退化草地群落稳定性和生产力维持具有重要意义。本文以松嫩草地顶级群落建群种羊草(Leymus chinensis)为研究对象,分析盐碱退化对羊草N、P化学计量特征的影响。结果表明:松嫩盐碱退化草地羊草相比较于中国北方草地羊草和草地植物具有较低的叶P含量(1.32 g·kg^(-1))、中等的叶N含量(18.90 g·kg^(-1))和略高的N/P(15.83)。叶N含量和N/P与土壤全氮、土壤碱解氮显著正相关;叶P含量与土壤全氮、土壤碱解氮显著负相关,其它因子与叶N、P和N/P相关性不明显。叶P含量与土壤氮的显著相关性和与土壤P含量的背离显示松嫩盐碱退化草地羊草可能存在一定的P限制。 N and P stoichiometry of constructive species of a climax community has an important influence on the stability and productivity of community. We chose Leymus chinensis, the constructive species of Songnen grassland community to study the effects of grassland degradation on N and P stoichiometry of L. chinensis under saline-alkali stress. There were lower leaf P content（ 1.32 g· kg-1 ） , medium leaf N content（ 18.90 g · kg-1） and slightly higher N/P（ 15.83 ） in degraded L. chinensis grassland compared with the L. chinensis grassland in the north of China. Leaf N and N/P were significantly positively correlated with soil total nitrogen and soil alkaline hydrolysis nitrogen. Leaf P was significantly negatively correlated with soil total nitrogen and soil alkaline hydrolysis nitrogen, but other factors were not significantly correlated with N, P and N/P. Both the significant correlations between leaf P content and soil N content and departure from leaf P content and soil P content common displayed that there might be a limitation of P in Songnen Plain at the saline alkali degradation of L. chinensis grassland.

作者赵龙王化梁正伟张衷华唐中华聂思铭赵冬梅

机构地区东北林业大学森林植物生态学教育部重点实验室黑龙江省科学院自然与生态研究所中国科学院东北地理与农业生态研究所

出处《植物研究》 CAS CSCD 北大核心 2016年第5期768-774,共7页 Bulletin of Botanical Research

基金国家自然科学基金(41271522) 中央高校基本科研业务费专项资金资助(2572015CA05)~~

关键词盐碱退化草地羊草化学计量氮磷土壤因子 saline-alkali degraded grassland Leymus chinensis stoichiometry N and P soil factors

分类号 Q142.3 [生物学—生态学]

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