哈尔滨城市绿地土壤肥力及其空间特征

doi:10.11707/j.1001-7488.20180902

摘要/Abstract

摘要： [目的]探讨哈尔滨城市森林绿地土壤肥力及其空间分布特征，以期为基于土壤肥力特征的城市绿色基础设施建设与管理提供支撑，进而提升城市植被生态服务功能。[方法]共采集哈尔滨市区道路林、景观林、单位附属林、生态公益林及郊区农田土壤257份，并测定9种土壤肥力相关指标，通过内梅罗指数法并参照全国第二次土壤普查分级标准对土壤肥力质量进行综合评价，结合ArcGIS绘制土壤各肥力指标空间分布图。[结果]参照全国第二次土壤普查6级制标准，哈尔滨市绿地土壤有机质含量为30~40 g·kg^-1，达到了2级（高）水平；全氮、水解性氮和有效磷含量分别为1~1.5 g·kg^-1、90~120 mg·kg^-1和<20 mg·kg^-1，为3级（中上）水平；全钾和速效钾含量较高，为2级（高）及以上水平；全磷含量低，为0.4~0.6 g·kg^-1，为4级（中下）水平；土壤密度为1.3~1.4 g·cm^-3，pH值为7.5-8.5；除速效钾外不同绿地土壤各肥力指标多表现为差异显著（P<0.05）；半方差分析表明，哈尔滨城市绿地有机质及土壤密度块基比≥ 75%，而全磷、水解性氮、有效磷、速效钾及综合肥力指数的块基比为25%~75%。[结论]哈尔滨城市绿地全磷含量较低，钾含量较高。全磷、全氮、土壤密度及水解性氮是土壤综合肥力水平提升的主要限制因子，有机质及土壤密度空间变异主要受随机因素影响，而全磷、水解性氮、有效磷、速效钾及综合肥力指数的空间变异则受随机因素和结构因素共同影响。应采取施用氮磷复合有机肥、控制钾肥、种植固氮植物等措施改善哈尔滨城市绿地土壤。

关键词: 城市绿地分类, 土壤有机质及氮磷钾, 土壤理化性质, 土壤肥力分级, 内梅罗综合肥力评价, 空间结构特征, 空间分布图

Abstract: [Objective] This study aims to provide a scientific basis to the construction and management of urban green land, hence, improving the ecological functionality of urban vegetation in Harbin City, through investigating the characteristics of fertility and its spatial distribution in the urban green land.[Method] 257 soil samples were collected from the following sites:roadside forests, institution-affiliated forests, landscape forests, ecological and public welfare forests, farmland. Nine indicators of soil fertility, including soil organic matter, total N, total P, total K, available N, available P, available K, pH, and soil density were measured. Classification of the 9indicatorsfollowed the classification criteria for soil nutrients listed in the 2nd National Soil Survey (6-grade evaluation) and a modified Nemorow formula. Additionally, spatial distribution of the 9parameterswas obtained by employing ArcGIS software.[Result] The results showed that the content of soil organic matter was graded as level 2 (high) with content of organic matters of 30-40 g·kg^-1 for most regions. For total N, available N and available P, they were graded as level 3, based on the contents of them of 1-1.5 g·kg^-1, 90-150 mg·kg^-1 and <20 mg·kg^-1 respectively. Considering the total K and available K, the levels were in the range of 50-100 g·kg^-1 and 150-200 mg·kg^-1, for most regions, which were graded as level 2 or higher. The total P reached the mid-low level(level 4), which showed a value ranging from 0.4 to 0.6 g·kg^-1 for most regions on the spatial map. The pH of the urban soil on the spatial map was 7.5-8.5, and soil density was 1.3-1.4 g·cm³. By reference to the value of, significant (P<0.05) differences were found among different types of green lands for all the studied parameters, with an exception of the available K. Spatial structure of soil indexes reveled that nugget/sill (C₀/C₀+C) of total P, available N, available P, available K and F were in the range of 25%-75%, while the values of both SOM and soil density were above 75%.[Conclusions] The total P content was low, while the content of total K was high the soil of green land in Harbin City. It was found that the total P, total N, soil density and available N were the main restraining factors for the soil fertility. In particular, the spatial variability of the studied parameters depended on various factors, showing that the total P, available N, available P, available K and F were influenced by structural factors and random factors, while the soil organic matter and soil density were influenced by random factors. Therefore, based on the findings in this study, measures such as application of N-P fertilizer, restricting the use of K fertilizer, and/or growing N-fixing plants, are needed to improve the soil fertility of green-land soil in Harbin City.

Key words: urban green space classification, soil organic matter and N, P, K, soil physical and chemical properties, grade of soil fertility, soil comprehensive fertility index via modified Nemorow formula, spatial structure, spatial distribution map

中图分类号:

S158

周伟, 王文杰, 何兴元, 张波, 肖路, 王琼, 吕海亮, 魏晨辉. 哈尔滨城市绿地土壤肥力及其空间特征[J]. 林业科学, 2018, 54(9): 9-17.

Zhou Wei, Wang Wenjie, He Xingyuan, Zhang Bo, Xiao Lu, Wang Qiong, Lü Hailiang, Wei Chenhui. Soil Fertility and Spatial Variability of Urban Green Land in Harbin[J]. Scientia Silvae Sinicae, 2018, 54(9): 9-17.

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