Impact of different grade roads on ecological networks: A case study of Fuzhou City, China

doi:10.13287/j.1001-9332.202402.023

Abstract

Abstract: The expansion of roads exacerbates the fragmentation of ecological networks and obstructs landscape connectivity. Scientific analysis of the impacts of different grades of roads on landscape connectivity and ecological networks is crucial for guiding road planning and ecological conservation. Based on the data of 2020 road network, land cover types, and digital elevation models, we used morphological spatial pattern analysis and circuit theory to construct ecological networks within different species dispersal distances (1, 3, 5, 10 km) in Fuzhou. We analyzed the impacts of roads of different grades (motorway, urban expressway, primary and secondary highway) on landscape connectivity at the landscape-patch-corridor scale. The results showed that at the landscape scale, overall landscape connectivity was significantly positively correlated with species dispersal distance. The motorway, urban expressway, primary and secondary highway had the lowest decline rate of overall landscape connectivity within a 10 km species dispersal range, being reduced by 15.6%, 5.3%, 1.5% and 5.2%, respectively. At the patch scale, in the comparison of roads of different grades, motorway led to the highest decline rate of patch connectivity within 1 and 5 km species dispersal range, while primary highway led to the highest decline rate of patch connectivity within 3 and 10 km species dispersal range. At the corridor scale, urban expressway led the highest increase rate of indices. The cost-weighted distance of the overall least-cost path, the ratio of cost-weighted distance to length, ove-rall effective resistance, and total corridor length within 5 km species dispersal range were increased by 43.4%, 33.2%, 57.3%, and 7.3%, respectively. As the distance of species dispersal increased, the patches with high importance were reduced from the northern, central, and northwestern regions to the northern regions, leading to a decrease in the living space of species, and the key corridors were gradually extending from the northwestern and southern regions to the central regions. Our results can guide the construction and optimization of Fuzhou’s ecological network from an overall perspective, and provide a scientific basis for biodiversity conservation, ecological restoration, and road network planning under the context of limited land resource utilization.

Key words: landscape connectivity, road grade, morphological spatial pattern analysis, circuit theory, species dispersal distance

JIA Dingyi, GUO Rongpeng, QIU Weiguo, WU Zhilong, LIN Sen, HU Xisheng. Impact of different grade roads on ecological networks: A case study of Fuzhou City, China[J]. Chinese Journal of Applied Ecology, 2024, 35(2): 489-500.

References

[1] Lenore F. Effects of habitat fragmentation on biodiver-sity. Annual Review of Ecology, Evolution and Systema-tics, 2003, 34: 487-516
[2] Pan J, Wang Y, Zhang Z. Identification and optimization of ecological network in arid inland river basin using MSPA and spatial syntax: Case study of Shule River Basin, NW China. Land, 2023, 12: 292
[3] Taylor PD. Connectivity is a vital element of landscape structure. Oikos, 1993, 68: 571-573
[4] 吴昌广, 周志翔, 王鹏程, 等. 景观连接度的概念、度量及其应用. 生态学报, 2010, 30(7): 1903-1910
[5] 陈利顶, 刘雪华, 傅伯杰. 卧龙自然保护区大熊猫生境破碎化研究. 生态学报, 1999, 19(3): 3-9
[6] 李慧, 李丽, 吴巩胜, 等. 基于电路理论的滇金丝猴生境景观连通性分析. 生态学报, 2018, 38(6): 2221-2228
[7] Cox DTC, Gardner AS, Gaston KJ. Diel niche variation in mammalian declines in the anthropocene. Scientific Reports, 2023, 13: 1-7
[8] 陈利顶, 傅伯杰. 景观连接度的生态学意义及其应用. 生态学杂志, 1996, 15(4): 37-42
[9] 邬建国. 景观生态学:概念与理论. 生态学杂志, 2000, 19(1): 42-52
[10] 刘骏杰, 陈璟如, 来燕妮, 等. 基于景观格局和连接度评价的生态网络方法优化与应用. 应用生态学报, 2019, 30(9): 3108-3118
[11] 林晋大, 多玲花, 邹自力. 城市扩张背景下景观破碎化动态演变及空间自相关分析: 以南昌市为例. 水土保持研究, 2022, 29(4): 362-369
[12] 杨志广, 蒋志云, 郭程轩, 等. 基于形态空间格局分析和最小累积阻力模型的广州市生态网络构建. 应用生态学报, 2018, 29(10): 3367-3376
[13] 史芳宁, 刘世梁, 安毅, 等. 城市化背景下景观破碎化及连接度动态变化研究: 以昆明市为例. 生态学报, 2020, 40(10): 3303-3314
[14] 李月辉, 胡远满, 李秀珍, 等. 道路生态研究进展. 应用生态学报, 2003, 14(3): 447-452
[15] 邹雨函, 贺怡, 王雪宏, 等. 道路对黄河三角洲河口湿地景观连接度的影响. 鲁东大学学报:自然科学版, 2022, 38(1): 9-17
[16] 于涛, 包安明, 刘铁, 等. 不同等级道路对玛纳斯河流域土地利用与景观格局的影响. 自然资源学报, 2019, 34(11): 2427-2439
[17] Liu SL, Dong YH, Deng L, et al. Forest fragmentation and landscape connectivity change associated with road network extension and city expansion: A case study in the Lancang River Valley. Ecological Indicators, 2014, 36: 160-168
[18] 吴钰茹, 吴晶晶, 毕晓丽, 等. 综合模型法评估黄河三角洲湿地景观连通性. 生态学报, 2022, 42(4): 1315-1326
[19] 陆晴, 刘根林, 闫冰, 等. 道路网络对景观格局及景观生态风险的影响: 以瑞兴于地区为例. 生态学杂志, 2022, 41(11): 2236-2244
[20] 刘阳, 欧小杨, 郑曦. 整合绿地结构与功能性连接分析的城市生物多样性保护规划. 风景园林, 2022, 29(1): 26-33
[21] 王琪, 朱佩娟, 文宁, 等. 道路交通网络对生态空间质量影响效应研究: 以长沙市为例. 湖南师范大学自然科学学报, 2023, 46(2): 84-94
[22] 于春辉. 新疆某自然保护区高等级道路动物通道的设置研究与应用. 公路, 2022, 67(2): 376-380
[23] Correa Ayram CA, Mendoza ME, Etter A, et al. Habitat connectivity in biodiversity conservation: A review of recent studies and applications. Progress in Physical Geography, 2016, 40: 7-37
[24] 黄杉杉, 马超. 黄土丘陵沟壑区道路建设和居民地扩张对生境破碎的影响. 生态科学, 2023, 42(1): 21-29
[25] Miao ZH, Pan L, Wang QZ, et al. Research on urban ecological network under the threat of road networks: A case study of Wuhan. ISPRS International Journal of Geo-Information, 2019, 8: 342
[26] 蔡青, 曾光明, 石林, 等. 基于栅格数据和图论算法的生态廊道识别. 地理研究, 2012, 31(8): 1523-1534
[27] Qi K, Fan Z, Ng CN, et al. Functional analysis of landscape connectivity at the landscape, component, and patch levels: A case study of Minqing County, Fuzhou City, China. Applied Geography, 2017, 80: 64-77
[28] McRae BH, Beier P. Circuit theory predicts gene flow in plant and animal populations. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104: 19885-19890
[29] McRae BH, Dickson BG, Keitt TH, et al. Using circuit theory to model connectivity in ecology, evolution, and conservation. Ecology, 2008, 10: 2712-2724
[30] 宋利利, 秦明周. 整合电路理论的生态廊道及其重要性识别. 应用生态学报, 2016, 27(10): 3344-3352
[31] 吴健生, 张理卿, 彭建, 等. 深圳市景观生态安全格局源地综合识别. 生态学报, 2013, 33(13): 4125-4133
[32] 陈瑾, 赵超超, 赵青, 等. 基于MSPA分析的福建省生态网络构建. 生态学报, 2023, 43(2): 603-614
[33] Schoville SD, Dalongeville A, Viennois G, et al. Preserving genetic connectivity in the European Alps Protected Area network. Biological Conservation, 2018, 218: 99-109
[34] 杜箫宇, 吕飞南, 王春雨, 等. 基于MSPA-Conefor-MCR的县域尺度生态网络构建: 以延庆区为例. 应用生态学报, 2023, 34(4): 1073-1082
[35] 俞孔坚. 生物保护的景观生态安全格局. 生态学报, 1999, 19(1): 10-17
[36] 陈春娣, 吴胜军, Meurk CD, 等. 阻力赋值对景观连接模拟的影响. 生态学报, 2015, 35(22): 7367-7376
[37] Wei JQ, Zhang Y, Liu Y, et al. The impact of different road grades on ecological networks in a mega-city Wuhan City, China. Ecological Indicators, 2022, 137: 108784
[38] 曲艺, 陆明. 生态网络规划研究进展与发展趋势. 城市发展研究, 2016, 23(8): 29-36
[39] Santiago S, Lucía PH. A new habitat availability index to integrate connectivity in landscape conservation planning: Comparison with existing indices and application to a case study. Landscape and Urban Planning, 2007, 83: 91-103
[40] 赵超超, 唐润, 翟瑞, 等. 福建省道路网络对森林覆盖连接度的影响. 山东理工大学学报:自然科学版, 2021, 35(5): 27-32
[41] Palfrey R, Oldekop JA, Holmes G. Privately protected areas increase global protected area coverage and connectivity. Nature Ecology & Evolution, 2022, 6: 730-737
[42] Zhang H, Zhang C, Hu T, et al. Exploration of roadway factors and habitat quality using InVEST. Transportation Research Part D: Transport and Environment, 2020, 87: 102-151
[43] Bani L, Baietto M, Bottoni L, et al. The use of focal species in designing a habitat network for a lowland area of Lombardy, Italy. Conservation Biology, 2002, 16: 826-831
[44] 国务院. “十四五”现代综合交通运输体系发展规划. 北京: 国务院, 2021