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生态学杂志 ›› 2023, Vol. 42 ›› Issue (11): 2569-2577.doi: 10.13292/j.1000-4890.202311.029

• 研究报告 • 上一篇    下一篇

微生境对黄檗幼树生长发育的影响

刘昌,路琦,汪生财,陈梦缘,邢韶华*   

  1. (北京林业大学生态与自然保护学院, 北京 100083)
  • 出版日期:2023-11-10 发布日期:2023-10-27

Effects of microhabitat on the growth of Phellodendron amurense saplings.

LIU Chang, LU Qi, WANG Shengcai, CHEN Mengyuan, XING Shaohua*   

  1. (School of Ecology and Nature Conservation, Beijing Forestry University, Beijing 100083, China).

  • Online:2023-11-10 Published:2023-10-27

摘要: 植物在生活史的不同阶段,影响其生长发育的主导环境因素也不同。植物幼年时期,林下微生境对其生长发育的影响更为显著。本研究以北京百花山国家级自然保护区内人工栽植的黄檗幼树为对象,测量了黄檗幼树个体周围的生物因素(同种和异种灌木和草本植物的邻体数量、成年木数量、成年木邻体指数)和非生物因素(叶面积指数、土壤养分、微地形指标),使用线性混合模型分析了环境因素对黄檗幼树生长发育的影响。结果表明:林下生物和非生物因素对黄檗幼树的生长均有一定的影响,但各环境因子对黄檗幼树生长的影响程度存在差异。成年木邻体效应对黄檗幼树生长的抑制作用最显著,贡献度占比为34.1%~47.7%;叶面积指数的影响次之,也呈负相关关系,贡献度占比为18.1%~25.3%;土壤全氮、有效钾和有机碳对黄檗幼树冠幅伸展起促进作用,贡献度占比为21.1%;微地形因子中,地形湿度指数对黄檗幼树生长有积极作用,解释占比为19.5%,坡度对黄檗幼树生长具有负面作用,但影响较弱,解释占比为11.5%。黄檗幼树周围的灌木、草本以及同种幼树对黄檗幼树生长没有明显的竞争作用。建议在黄檗迁地保护时,选择微地形平整、土壤湿润肥沃、富含氮钾元素并具有一定冠层遮蔽的落叶阔叶林区域。


关键词: 微生境, 微地形, 黄檗, 线性混合模型

Abstract: The dominant factors affecting plant growth vary across the stages of life history. Understory microhabitats play a significant role on plant growth and development during juvenile stage. In 2021, we surveyed Phellodendron amurense saplings planted in 2014 beneath a natural forest in Baihuashan Nature Reserve, and measured the biotic factors (density of con and heterospecific seedling neighbors, density of herbaceous and shrub neighbors, and adult neighborhood index) and abiotic factors (leaf area index, soil nutrients, and microtopography indices) around the saplings. Linear mixed models were used to assess the effects of biotic factors and abiotic microhabitat factors on the growth rates of the established saplings. The results showed that both biotic and abiotic factors affected the growth of P. amurense saplings, with different magnitudes in their impacts. Heterospecific adult neighbors had the most significant negative effect on the growth of saplings, explaining 34.1%-47.7% of the variance in their growth. Light intensity also had a negative effect, which explained 18.1%-25.3% of the variance. Soil nitrogen, available potassium, and organic carbon promoted the crown extension of P. amurense, accounting for 21.1% of the variance of the growth. Among the microtopographic factors, the topographic wetness index had a significant positive impact on the growth of saplings, explaining 19.5% of the variance, whereas slope had a negative but weak effect on the growth, accounting for 11.5% of the variance. Shrubs and grasses and the conspecifics did not affect the growth of P. amurense saplings. In conclusion, deciduous broad-leaved forests with flat microtopography, moist and fertile soil, rich in nitrogen and potassium, and high canopy density would facilitate the ex situ conservation of P. amurense.


Key words: microhabitat, microtopography, Phellodendron amurense, linear mixed model.