盐穗木种群空间点格局对地下水埋深的响应

doi:10.11707/j.1001-7488.20151103

摘要/Abstract

摘要： [目的]以准噶尔盆地南缘洪积扇浅层(<2.5 m)、中度(2.5~4.5 m)和深度(>4.5 m)3个地下水埋深典型地段上的盐穗木种群为研究对象,研究不同地下水埋深、不同发育阶段种群的空间分布格局及其空间关联性,探讨地下水埋深对盐穗木种群空间格局形成及种群维持机制的影响。[方法]在准噶尔盆地南缘盐穗木分布区建立3块1 hm²的固定样地,采用网格法调查盐穗木种群分布数据;利用空间点格局分析中常用的Ripley's K函数对盐穗木种群的空间格局、种内关联性以及与地下水埋深的关系进行研究。[结果]随着地下水位加深,盐穗木种群的幼苗补充数量减少十分严重,而枯立木急剧增多,种群结构变化明显;在3个地下水埋深生境中,盐穗木种群各发育阶段在小尺度上均表现出聚集分布,随尺度增加各发育阶段的聚集强度减弱,其中浅层和中度地下水埋深地段在50 m的范围内聚集,而深度地下水埋深地段均趋于随机分布;随着地下水埋深的增加,种群聚集强度增加;盐穗木幼苗具有明显的聚集分布和最大的聚集强度,从幼苗到成年植株则表现出聚集强度和聚集尺度均降低;在浅层和中度地下水埋深地段,盐穗木各发育阶段之间在小尺度上均强烈正关联,而在大尺度上浅层地下水埋深地段表现出较强的负关联,中度地下水埋深地段在大尺度上为无关联或弱的负关联;深度地下水埋深地段盐穗木种群各发育阶段之间在整体上均趋于无关联。[结论]准噶尔盆地南缘地下水埋深对盐穗木种群空间格局和种内关联影响较大,尤其是深度地下水埋深严重制约种群空间格局的形成,而中度地下水埋深地段的盐穗木种群可以通过人工措施进行恢复,维持种群稳定的空间格局。

关键词: 空间格局, 空间关联, g(r)函数, 盐穗木, 准噶尔盆地

Abstract: [Objective]The objectives were by investigating Halostachys caspica populations with three underwater depths:shallow (<2.5 m), middle (2.5-4.5 m) and deep (>4.5 m) in the sample plots, alluvial fan of south Junggar basin to study spatial pattern and spatial association of the populations among three underwater depths and at development stages, and to explore the impacts of underground water depth on the formation of spatial patterns and mechanism of maintaining H. caspica populations. [Method]Three 1 hm² permanent sample plots were established and grid method was used to investigate population distribution in south Junggar basin. Ripley's K function was employed to study spatial pattern, intraspecific association and their relationships with underground water depth.[Result]The number of regenerated young seedlings decreased severely with the increase of underground water depth. The population structure changed obviously due to increased dead standing trees. At different developmental stages, all H. caspica populations displayed aggregated distributions at small scales in all the three habitats. With the increase of scales, aggregation intensity weakened at different developmental stages. It was found that aggregated distribution was at 50 m scale in areas with shallow and middle underground water depth, while the population spatial pattern tended to be random distribution in areas with deep underground water. The population aggregation intensity increased with underground water depth, and young seedlings of H. caspica appeared to have obvious aggregation distribution and maximum aggregation intensity. The aggregation intensity and the scale of H. caspica population decreased from seedlings to adult trees. At small scales, intense positive association occurred in areas with shallow and middle underground water depth, while negative association was found among different population developmental stages in areas with shallow underwater depth. No association or weak negative association at big scales in areas with middle underground water depth. The populations all tended to have no association among different developmental stages in areas with deep underground water depth.[Conclusion]Underground water depth has important effect on spatial pattern and intraspecific association of H. caspica population in south Junggar basin. Especially, the deep underground water depth severely restricted the spatial pattern of the populations. In areas with middle underground water depth, the populations may be recovered by artificial measures to maintain the stable spatial pattern.

Key words: spatial pattern, spatial association, g(r) function, Halostachys caspica, Junggar basin

中图分类号:

S718.54

王梅, 赵晨光, 王莹, 楚光明. 盐穗木种群空间点格局对地下水埋深的响应[J]. 林业科学, 2015, 51(11): 17-24.

Wang Mei, Zhao Chenguang, Wang Ying, Chu Guangming. Response of Spatial Point Pattern of Halostachys caspica Population to Underground Water Depth[J]. Scientia Silvae Sinicae, 2015, 51(11): 17-24.

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