关帝山云杉次生林土壤的空间异质性及其与地形相关性

doi:10.16843/j.sswc.2017.04.003

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摘要为揭示森林土壤空间变异特征及其变异机制，参照CTFS样地土壤采样方案，在关帝山4 hm²云杉次生林样地199个采样点进行土壤取样和测定，运用经典统计方法分析寒温性云杉林土壤pH值、有效氮、有效磷、有效钾和有机质的水平和垂直空间分布特征，应用地统计学和ArcGIS插值的方法，重点分析了0~10 cm层土壤性质的空间异质性及其分布格局，并基于RDA排序和方差分解定量评价地形因子对土壤各指标空间变异的影响程度和解释量。结果表明：云杉次生林土壤的pH值、有效氮、有效磷、有效钾和有机质含量呈明显的水平及垂直空间变异，0~10 cm层土壤上述5个指标的变异系数分别为8.78%、41.15%、58.36%、46.60%和48.38%；土壤变异的空间自相关范围为4.9~58.8 m，pH值和有效氮呈中等程度的空间自相关，有效磷、有效钾和有机质呈强烈的空间自相关变异；有效氮、有机质和有效钾呈相似的空间斑块状分布格局，即样地有效氮含量高的斑块中有机质和有效钾含量也高。pH值和有效磷则表现出相反的斑块分布格局；地形因子中，pH值、有效氮和有效磷受海拔影响最大，其中，海拔与pH值、有效磷呈正相关，分别解释其空间变异的40.43%和28.81%，而与有效氮呈负相关，能单独解释其空间变异的19.48%。凹凸度对有效钾和有机质的影响最大，可分别解释9.37%和6.88%的有效钾和有机质的空间变异，与这2个土壤性质指标为负相关。研究可为深入认识华北地区植物分布和物种共存提供基础依据。

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关键词 ：空间异质性, 地形因子, 方差分解, 云杉次生林

Abstract：[Background] Soil properties to a large degree showed the spatial self-correlation variation characteristics. Topography is usually an important source of soil variation. Quantitative analysis of spatial heterogeneity of soil and its correlation with topography is helpful for revealing the potential mechanism of soil variation. [Methods] Referring to soil sampling scheme of CTFS, we collected 199 soil samples from a 4 hm² secondary Picea forest of Guandi Mountain and completed the soil properties determination. The horizontal and vertical space distribution characteristics of PH, organic matter, available nitrogen, phosphorus and potassium were analyzed using the classical statistical methods, spatial heterogeneity of soil properties at 0-10 cm layer and their distribution patterns were acquired through geo-statistics and ArcGIS interpolation, and the effects of terrain factors on spatial heterogeneity of soil properties were quantitatively assessed by RDA sorting and variance decomposition. [Results] The coefficient of variation for the soil pH, organic matter, available nitrogen, available phosphorus and available potassium was 8.78%、48.38%、41.15%、58.36%、46.60%, respectively. The five factors showed the spatial self-correlation variation at 4.9-58.8 m scale range, and a moderate degree of self-correlation was evaluated for pH and available nitrogen but a strong degree of self-correlation was evaluated for organic matter, available phosphorus and available potassium. Organic matter, available nitrogen and available potassium showed analogical spatial plaque distribution pattern, that is, the contents of organic matter and available potassium were also high in the plaque where there was available nitrogen in high content, while the soil pH and available phosphorus showed an opposite distribution pattern. Among the terrain factors, elevation had the strongest effects on the soil pH, available nitrogen and phosphorus, soil pH and available phosphorus had positive correlation with elevation, and the elevation explained 40.43% and 28.81% of the spatial variability of soil pH and available phosphorus, respectively, but available nitrogen had negative correlation with elevation and the elevation explained 19.48% of the spatial variability of available nitrogen independently. Convexity had the strongest negative effects on available potassium and organic matter, and it explained 9.37% and 6.88% of the spatial variability of available potassium and organic matter. [Conclusions] Soil properties showed structural heterogeneity in space and topography factors had important effects on the variation of soil factors. The experimental results can provide the basis for understanding the distribution and coexistence of tree species in North China.

Key words： spatial heterogeneity terrain factors variance decomposition secondary Picea forest

收稿日期: 2017-03-03

PACS:

S718.5

基金资助:国家自然科学基金"密度制约和环境异质性对云杉次生林物种更新及功能性状的影响研究"（31470631），"寒温性云杉次生林树种更新过程中幼苗生态化学计量特征的时空格局及环境响应"（31670630）

通讯作者: 闫海冰(1978-),男,博士,副教授。主要研究方向:森林资源培育与森林生态学。E-mail:yhb5188@126.com E-mail: yhb5188@126.com

作者简介: 杨秀清(1976-),女,博士研究生。主要研究方向:森林资源培育与森林生态学。E-mail:xiuqingy2002@126.com

引用本文:

杨秀清, 史婵, 王旭刚, 马慧晶, 闫海冰. 关帝山云杉次生林土壤的空间异质性及其与地形相关性[J]. 中国水土保持科学, 2017, 15(4): 16-24.
YANG Xiuqing, SHI Chan, WANG Xugang, MA Huijing, YAN Haibing. Spatial heterogeneity of soil in the secondary Picea forest of Guandi Mountain and its correlation with topography. SSWC, 2017, 15(4): 16-24.

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http://journal12.magtechjournal.com/Jweb_stbc/CN/10.16843/j.sswc.2017.04.003 或 http://journal12.magtechjournal.com/Jweb_stbc/CN/Y2017/V15/I4/16

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