WANG Ning,ZHANG Youli,WANG Baitian,et al.Stoichiometry of Carbon, Nitrogen and Phosphorus in Pinus tabulaeformis Carr. Forest Ecosystems in Shanxi Province, China[J].Research of Soil and Water Conservation,2015,22(01):72-79.
山西省油松林生态系统碳氮磷化学计量特征
- Title:
- Stoichiometry of Carbon, Nitrogen and Phosphorus in Pinus tabulaeformis Carr. Forest Ecosystems in Shanxi Province, China
- Keywords:
- Pinus tabulaeformis Carr.; forest ecosystem; content of carbon; nitrogen and phosphorus; ecological stoichiometry; Shanxi Province
- 分类号:
- S718;Q143
- 摘要:
- 为了评价山西省油松林生态系统的生态化学计量特征,以山西省油松人工幼龄林(AY)、人工中龄林(AM)、天然幼龄林(NY)和天然中龄林(NM)为研究对象,通过38块标准地实测数据,探讨了4种森林类型的化学计量特征。结果显示:1)AY,AM,NY和NM乔木叶片的C∶N∶P分别为276∶8∶1,283∶8∶1,458∶12∶1和362∶11∶1,灌木叶片的C∶N∶P分别为181∶11∶1,132∶8∶1,228∶9∶1和221∶15∶1,草本叶片的C∶N∶P分别为211∶8∶1,200∶9∶1,190∶8∶1和230∶11∶1,凋落物的C∶N∶P分别为347∶3∶1,246∶5∶1,507∶9∶1和327∶9∶1,土壤(0—100 cm)的C∶N∶P分别为23∶6∶1,37∶7∶1,28∶6∶1和30∶5∶1;2)4种类型的C∶N和C∶P基本都表现为凋落物 > 叶片 > 土壤,凋落物和叶片的C∶N和C∶P表现为AY > AM,NY > NM,土壤的C∶N和C∶P则为AM > AY,NM > NY,而N∶P则表现为叶片 > 凋落物 > 土壤,在林龄上表现规律不明显,植物叶片N∶P < 14,存在N限制;3)4种类型植物叶片C∶P均表现为乔木叶片 > 草本叶片 > 灌木叶片,表明油松林生态系统中乔木叶建成效率最高,而灌木叶建成效率最低;4)4种类型土壤层随着土层厚度的增加,C∶N表现出下降规律,C∶P和N∶P规律表现不明显。研究结果表明,4种生态系统的叶片、凋落物和土壤的化学计量特征具有一致性。
- Abstract:
- This paper reports the stoichiometry of carbon∶nitrogen∶phosphorus (C∶N∶P) in four age groups of Pinus tabulaeformis Carr. (also called Chinese pine) forest (artificial young forest, AY; artificial middle-aged forest, AM; natural young forest, NY; natural middle-aged forest, NM) in Shanxi Province, China. The results revealed the followings: (1) The mass-based average C∶N∶P ratios of tree species (shrubs, herbs, litter, soil depth of 100 cm) for the four forest types were 276∶8∶1 in AY, 283∶8∶1 in AM, 458∶12∶1 in NY, and 362∶11∶1 in NM. (2) Regardless of forest ages, the C∶N and C∶P ratios decreased in the order, litter > leaves > soil. The C∶N and C∶P ratios were both greater in the litter and leaves of young forest trees than in the litter and leaves of middle-aged forest trees, and greater in the soil of middle-aged forest than in the soil of young forest. The N∶P ratio was greater in leaves than in litter, and greater in litter than in the soil, and showed variation according to stand ages. For all the species in the forests, the N∶P ratio was consistently less than 14, suggesting that there was N limitation. (3) The C∶P ratio for the leaves of plants growing in the four forest types decreased in the order, arbor leaf > herb leaf > shrub leaf. (4) The C∶N ratio decreased with the increase of soil depth, whereas both the C∶P and N∶P ratios did not show a consistent variation trend along soil depth. (5) The foliar C∶N∶P stoichiometry of plants in the forests did not exhibit a consistent variation trend with stand ages.
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备注/Memo
收稿日期:2014-12-11;改回日期:2014-12-29。
基金项目:中科院战略先导专项专题“暖温带落叶阔叶混交林区域山西中部森林固碳现状速率和潜力研究”(XDAO5050203-04-01)
作者简介:王宁(1977-),男,陕西合阳人,讲师,博士,主要研究方向为生态环境工程。E-mail:soilandwater@163.com
通讯作者:王百田(1958-),男,陕西富平人,教授,博士生导师,研究方向为生态环境工程。E-mail:13910595782@163.com