高级检索

    天然油松叶−枝−根氮磷含量随降水和温度的变化规律

    Changing patterns of nitrogen and phosphorus contents in leaf-branch-root of natural Pinus tabuliformis with precipitation and temperature

    • 摘要:
      目的 对油松叶、枝、根的氮、磷含量随水热变化的响应规律进行研究,有助于加深对我国暖温带地区森林植物应对气候变化策略的认识。
      方法 本文基于生态化学计量学理论,在我国天然油松林主要分布区选择7个代表性样点,对优势种油松叶、枝、根的氮、磷含量进行定量分析。
      结果 (1)油松叶、枝、根器官间氮、磷含量存在显著差异,叶的氮、磷含量均高于枝和根的氮、磷含量,其中当年生叶、当年生枝的氮、磷含量高于多年生叶、多年生枝的氮、磷含量。吸收根氮、磷含量高于次生根氮、磷含量。当年生叶、当年生枝的氮磷比低于多年生叶、多年生枝的氮磷比,次生根氮磷比高于吸收根氮磷比。(2)油松叶、枝、根的氮、磷含量的变异程度存在差异,整体变异系数范围为12.3% ~ 44.4%,其中吸收根磷含量的变异系数最大,多年生叶氮含量的变异系数最小。(3)油松不同器官的氮磷化学计量特征随环境变化的响应存在差异,油松多年生叶氮含量、多年生及当年生枝氮、磷含量随降水量的增加呈显著下降的趋势。多年生及当年生叶磷含量、枝磷含量均随温度的升高呈显著上升的趋势。多年生及当年生叶氮磷比、枝氮磷比随温度的升高呈显著下降的趋势。次生根磷含量随温度的升高呈显著上升的趋势,次生根氮磷比随温度升高呈显著下降的趋势。
      结论 降水、温度对我国天然油松林优势物种油松叶、枝、根的氮磷化学计量特征有显著影响,不同器官应对这两个环境因子的响应趋势及适应机制不同。

       

      Abstract:
      Objective Studying the response of nitrogen and phosphorus contents in leaf-root of Pinus tabuliformis to hydrothermal changes can enhance our understanding of the strategies for forest community plants in warm temperate regions of China to confront the challenges posed by climatic shifts.
      Method Seven representative sample locations were selected in the main distribution areas of natural P. tabuliformis forests in China, and the nitrogen (N) and phosphorus (P) contents in the leaves, branches, and roots of P. tabuliformis were meticulously assessed according to the theory of ecological stoichiometry.
      Result (1) Differences in nitrogen (N) and phosphorus (P) contents among various plant organs of leaves, branches, and roots were evident. Notably, concentrations of N and P in leaves surpassed those in branches and roots. Additionally, both current leaves and branches exhibited higher N and P levels compared with their perennial counterparts, while absorbed roots displayed elevated N and P contents compared with secondary roots. The N∶P ratios in current leaves and branches were lower than those in perennial leaves and in perennial branches, whereas secondary roots demonstrated a higher N∶P ratio than absorbed roots. (2) Variability in nitrogen (N) and phosphorus (P) content differed among leaves, branches, and roots, as indicated by the overall coefficient of variation ranging from 12.3% to 44.4%. Notably, the highest variability was observed in absorbed roots, contrasting with the lowest variability observed in perennial leaves. (3) The adaptive responses of nitrogen (N) and phosphorus (P) stoichiometry within distinct organs of P. tabuliformis to environmental shifts exhibited notable variations. Specifically, the N content in perennial leaves, perennial branches, and current branches, along with the P content in perennial branches and both current branches and leaves, experienced significant decreases with escalating precipitation. Conversely, a significant uptrend in P content was observed in perennial leaves, perennial branches, current leaves, and current branches as the temperature increased. Simultaneously, the N∶P ratio in perennial leaves, perennial branches, and both current leaves and branches demonstrated substantial declines with rising temperatures. Notably, the P content in secondary roots displayed a marked increase with elevated temperature, whereas the N∶P ratio in secondary roots exhibited a notable decrease.
      Conclusion Both precipitation and temperature exert significant impacts on the nitrogen (N) and phosphorus (P) stoichiometry in the leaves, branches, and roots of P. tabuliformis. The diverse response trends and adaptation mechanisms of distinct organs to these two environmental factors exhibite marked variations.

       

    /

    返回文章
    返回