基于形态学空间格局方法的北京市六环内城市林木树冠覆盖斑块动态特征

doi:10.11707/j.1001-7488.LYKX20210874

摘要/Abstract

摘要：

目的: 明晰北京市城区城市林木树冠覆盖（urban tree canopy, UTC）斑块总体形态特点，揭示城市化进程中UTC斑块形态特征变化的时、空演化特征，以期为今后城区的城市森林建设和现有城市林木保护提供借鉴。方法: 本研究以北京市六环内为研究区，基于2002、2013和2019年3期高分辨率遥感影像提取UTC斑块，采用形态学空间格局分析方法，分析近20年来北京城区UTC斑块形态特征组成状况，并结合转移矩阵与相对贡献度等方法指标，识别北京市城区UTC形态特征的主要转换类型及其空间分异特点。结果: 2002—2019年间，北京城区UTC从2002年的387.93 km²增加到2019年的771.14 km²。其中，2002—2013年间，北京市城区UTC增幅达282.92 km²，显著高于2013—2019年间的97.39 km²。3期UTC斑块的形态特征组成却较为一致，孤岛、核心区与桥接区是UTC斑块主要的形态特征，三者总和均占各期UTC总面积的80%以上；而UTC的边缘、环道区、分支以及孔隙则是次要的形态特征。从时间变化来看，在2002—2013年和2013—2019年2个时段，UTC孤岛与其他地类之间的转换均为UTC变化的主要类型，其面积分别在UTC转换总面积中占30%和25%。但同时，两个时段内UTC形态特征转换仍存在一定差异。在2002—2013年间，与UTC核心区相关的转换类型面积占比较大，在同期UTC转换总面积中占比达23.12%；而在2013—2019年间，与UTC桥接区相关的转换类型面积占比则较大，在同期UTC转换总面积中占比达35.22%。相较于前一时段UTC核心区的动态变化较为明显，在后一时段北京市城区UTC形态特征转换则更多地表现为与桥接区相关的变化。从空间变化来看，北京市4环内区域主要以UTC孤岛变化为主要的转换类型，而四环外则以UTC核心区与桥接区变化为主。结论: 近20年来，北京市城区林木树冠覆盖大幅提升，城市绿化工程取得巨大成效，UTC孤岛、核心区和桥接区是北京市六环内UTC斑块的主要形态特征。随着城市发展，UTC斑块的形态特征主要转换类型逐渐从以核心区相关的转换变为与桥接区相关的转换。UTC斑块形态特征转换呈现城乡梯度分布特征，从市中心向外，UTC斑块形态特征的主要转换类型从与孤岛相关的转换变为与桥接区和核心区相关的转换。今后，城市森林建设需侧重于维持和提升城市森林斑块之间的连接度，并强化市中心残留林木斑块的保护。

关键词: 城市林木树冠覆盖斑块, 形态学空间格局分析, 时空动态, 北京

Abstract:

Objective: This study aims to clarify the overall morphological characteristics of urban tree canopy (UTC) patches in the urban area of Beijing, and reveal the spatio-temporal dynamics of UTC patch morphology during the urbanization process, so as to provide the scientific reference for the planning and construction of urban forest in the future. Method: In this study, we first extracted the UTC patches within the 6^th Ring road of Beijing in 2002, 2013 and 2019 based on the high-resolution remote sensing images, and then analyzed the composition of patch morphological characteristics with the morphological spatial pattern analysis (MSPA) method, and finally revealed the spatial discrepancy of UTC transition using transition matrix and the relative contribution index method. Result: The UTC within the 6^th Ring road of Beijing increased from 387.93 km² in 2002 to 771.14 km² in 2019, showing a large expansion of UTC during the study period. However, there existed differences between the period of 2002–2013 and 2013–2019. From 2002 to 2013 the UTC reached to 282.92 km², which was apparently larger than that from 2013 to 2019 (97.39 km²). Furthermore, the morphological composition was rather steady throughout the study period. The islet, core and bridge were the main morphological types of UTC patches, since the total area of these three types comprised of over 80% of UTC in 2002, 2013 and 2019. The edge, loop, branch and perforation were the secondary types. During the study period, the transition between other urban land types and the islet of UTC was the main transition type of UTC, accounting for 30% and 25% of the total UTC conversion area during the periods of 2002–2013 and 2013–2019, respectively. Nevertheless, there were differences in UTC dynamics between these two sub-periods. Between 2002 and 2013, the transition related to the core of UTC patches had a relatively large areal ratio (approximately 23.12%), while the transition related to the bridge of UTC patches had a relatively large areal ratio (approximately 35.22%) between 2013 and 2019. It was suggested that the UTC transition before 2013 was to a larger extent characterized as the dynamics of UTC core, while UTC transition after 2013 was characterized as the dynamics of UTC bridge. From the perspective of spatial changes, the transition related to the UTC islet mainly clustered within the 4^th Ring road, while the transitions related to the UTC core and bridge were located between the 4^th and 6^th Ring-road. Conclusion: In the past two decades, the UTC within the 6^th Ring road in Beijing has expanded, mainly due to the urban greening projects. The islet, core and bridge are the main morphological characteristics of UTC patches within the 6^th Ring road in Beijing. With the development of the city, the main transition type of morphological characteristics of UTC patches gradually changes from the transition related to the core to the transition related to the bridging. The transitions of UTC patch morphological features present a gradient distribution between urban and rural areas, that is, from the city center to the outside, the main transition type of UTC patch morphological characteristics changes from the transition related to the islet to the transition related to the core and bridge. In the future, urban forest construction should focus on maintaining and improving the connectivity between urban forest patches and strengthening the protection of remnant forest patches in the city center.

Key words: urban tree canopy patches, morphological spatial pattern analysis, spatio-temporal dynamics, Beijing.

中图分类号:

仇宽彪,李晓婷,成军锋,贾宝全. 基于形态学空间格局方法的北京市六环内城市林木树冠覆盖斑块动态特征[J]. 林业科学, 2023, 59(5): 11-20.

Kuanbiao Qiu,Xiaoting Li,Junfeng Cheng,Baoquan Jia. Dynamics of Urban Tree Canopy Patches within the 6^th Ring Road in Beijing Based on Morphological Spatial Pattern Analysis (MSPA) Method[J]. Scientia Silvae Sinicae, 2023, 59(5): 11-20.

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形状特征 Morphological elements	生态学含义 Ecological definition
核心区 Core	景观中较大的生境斑块，可为物种提供较大的栖息地，是重要的生态源地 The large habitat patches in the landscape which can provide habitats for species and are important ecological sources
孤岛 Islet	彼此不相连的孤立、破碎的小斑块，斑块之间连接度低，物质、能量交流可能性较小 Isolated and fragmented small patches that are not connected to each other, with low connectivity between patches and small probability of material and energy exchange
孔隙 Perforation	核心区内部边缘，即核心区与内部其他类型斑块之间的过渡区域 The inner edge of the core area, that is, the transition area between the core area and other types of patches inside
边缘 Edge	核心区外部边缘，即核心区与外部其他类型斑块之间的过渡区域 The outer edge of the core area, that is, the transition area between the core area and other types of patches outside
环道区 Loop	连接同一核心区的廊道，是同一核心区内物种迁移的捷径 Corridors connecting the same core area as a shortcut for species migration within the same core area
桥接区 Bridge	连通核心区的狭长区域，是景观中斑块连接的廊道 The narrow and long area connecting the core areas as a corridor connecting patches in the landscape
分支 Branch	只有一端与边缘、桥接区、环道区或孔隙相连的区域 The area connecting at one end to edge, perforation, bridge, or loop

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