Research advances in the effects of urbanization on birds based on bibliometrics

doi:10.13287/j.1001-9332.202601.034

Abstract

Abstract: Birds are key indicator taxa for assessing urban ecosystems condition, as their diversity, distributional patterns, and community structure reflect environmental quality in urban settings. To synthesize the research progress of urban birds, we employed bibliometric analysis and inductive synthesis to analyze the distribution of research hotspots, evolutionary trajectories, and thematic keyword categories, based on literature indexed in CNKI and the Web of Science Core Collection over the past two decades. We found that research in both contexts shares a common focus on the impacts of urbanization on bird communities and on biodiversity conservation. Research in China exhibits a policy-driven orientation toward conservation planning practice, whereas international research emphasize individual- to population-level behavioral and physiological response mechanisms, with comparatively more mature frameworks. Current research on urban birds focus on five main aspects: 1) the effects of urbanization on bird community composition and structure; 2) the influence of urban green space configuration and vegetation attributes on birds; 3) behavior and survival adaptations under urbanization; 4) the effects of urban environments on morphology and physiology; and 5) planning of urban ecological parks grounded in bird conservation. Future works should highlight the significance of ecosystem services provided by urban birds, advance conservation from multiple dimensions, and enhance both quality and efficiency through integrating theory with practice.

Key words: urban landscape, green spaces characteristic, biodiversity, habitat, ecosystem service

LIU Yue, LU Xunling, LI Wanying, LU Kaixin, YU Jinhai. Research advances in the effects of urbanization on birds based on bibliometrics[J]. Chinese Journal of Applied Ecology, 2026, 37(1): 280-294.

References

[1] Chen JL, Gao JL, Yuan F. Growth type and functional trajectories: An empirical study of urban expansion in Nanjing, China. PLoS One, 2016, 11: e0148389
[2] Seto KC, Güneralp B, Hutyra LR. Global forecasts of urban expansion to 2030 and direct impacts on biodiversity and carbon pools. Proceedings of the National Aca-demy of Sciences of the United States of America, 2012, 109: 16083-16088
[3] McKinney ML. Effects of urbanization on species richness: A review of plants and animals. Urban Ecosystems, 2008, 11: 161-176
[4] 石春芳, 赵明华. 鸟类——城市生态环境的指示种. 内蒙古科技与经济, 2005(3): 125-126
[5] Atlegrim O. Exclusion of birds from bilberry stands: Impact on insect larval density and damage to the bilberry. Oecologia, 1989, 79: 136-139
[6] Figuerola J, Green AJ. Dispersal of aquatic organisms by waterbirds: A review of past research and priorities for future studies. Freshwater Biology, 2002, 47: 483-494
[7] Şekercioğlu ÇH, Wenny DG, Whelan CJ. Why Birds Matter: Avian Ecological Function and Ecosystem Ser-vices. Chicago, IL, USA: University of Chicago Press, 2016: 318-320
[8] 邹学慧. 宋词鸟意象文化意蕴. 文艺评论, 2011(8): 78-82
[9] 吴雨晨, 林岚, 刘群, 等. 福建师范大学鸟类资源空间分布及观鸟研学活动设计: 基于自然教育视角. 地理教学, 2023(14): 40-44
[10] 张征恺, 黄甘霖. 中国城市鸟类学研究进展. 生态学报, 2018, 38(10): 3357-3367
[11] Pritchard A. Statistical bibliography or bibliometrics. Journal of Documentation, 1969, 25: 348-349
[12] Zupic I, Čater T. Bibliometric methods in management and organization. Organizational Research Methods, 2015, 18: 429-472
[13] 马程伟, 文超祥. 适应气候变化的海岸带韧性研究综述: 基于文献计量分析. 生态学报, 2024, 44(5): 2173-2186
[14] Garrard GE, Williams NSG, Mata L, et al. Biodiversity sensitive urban design. Conservation Letters, 2018, 11: e12411
[15] Chen XM, Wang YP. A systematic review of avian responses to urbanization in China: Research trends, current insights, and future directions. Avian Research, 2025, 16: 100292
[16] 刘越强, 沈泽昊, 李娜. 滇中高原半湿润常绿阔叶林斑块的鸟类多样性. 应用生态学报, 2024, 35(7): 1979-1987
[17] 赵伊琳, 王成, 白梓彤, 等. 城市化鸟类群落变化及其与城市植被的关系. 生态学报, 2021, 41(2): 479-489
[18] Xu WZ, Fu WC, Dong JY, et al. Bird communities vary under different urbanization types: A case study in mountain parks of Fuzhou, China. Diversity, 2022, 14: 555
[19] Huang PL, Zheng DL, Yan YJ, et al. Effects of landscape features on bird community in winter urban parks. Animals, 2022, 12: 3442
[20] Morelli F, Benedetti Y, Su TP, et al. Taxonomic diversity, functional diversity and evolutionary uniqueness in bird communities of Beijing’s urban parks: Effects of land use and vegetation structure. Urban Forestry & Urban Greening, 2017, 23: 84-92
[21] 汪国海, 唐创斌, 韦丽娟, 等. 城市绿地中鸟类对小叶榕果实的取食和传播作用. 安徽农业科学, 2023, 51(7): 53-55, 63
[22] 张达, 曾坚, 艾合麦提·那麦提. 高强度开发地区鸟类自然保护地保护空缺识别: 以天津市为例. 应用生态学报, 2023, 34(6): 1621-1629
[23] Yang XR, Tan XW, Chen CW, et al. The influence of urban park characteristics on bird diversity in Nanjing, China. Avian Research, 2020, 11: 45
[24] 李红梅. 基于视听交互模拟的合肥市常见鸟鸣感知偏好研究. 硕士论文. 合肥: 安徽建筑大学, 2023
[25] 聂玮, 李红梅, 赵瑾瑜, 等. 城市绿地常见鸟鸣感知偏好和恢复效益研究. 淮阴工学院学报, 2022, 31(5): 81-89, 96
[26] 张群, 李博. 崇明东滩鸟类栖息地优化区海三棱藨草野外恢复实践. 应用生态学报, 2023, 34(10): 2663-2671
[27] 王云才, 卢星昊, 王若静. 上海主城区绿地对鸟类多样性的影响及其边际效应. 中国城市林业, 2023, 21(4): 1-7
[28] 王欣悦, 王传文, 梁蕙仪, 等. 基于鸟类栖息地的西安市生态网络构建及景观优化. 应用生态学报, 2025, 36(8): 2525-2534
[29] 周诗文, 李绥, 张雨阳. 基于邻域景观兼容性改进电路理论的沈阳市鸟类生境网络构建. 应用生态学报, 2025, 36(8): 2515-2524
[30] 杨刚, 王勇, 许洁, 等. 城市公园生境类型对鸟类群落的影响. 生态学报, 2015, 35(12): 4186-4195
[31] Yang G, Xu J, Wang Y, et al. Evaluation of microhabitats for wild birds in a Shanghai urban area park. Urban Forestry & Urban Greening, 2015, 14: 246-254
[32] Xu WZ, Yu J, Huang PL, et al. Relationship between vegetation habitats and bird communities in urban mountain parks. Animals, 2022, 12: 2470
[33] MacGregor-Fors I, Morales-Pérez L, Schondube JE. Migrating to the city: Responses of neotropical migrant bird communities to urbanization. The Condor, 2010, 112: 711-717
[34] Sidemo-Holm W, Ekroos J, Reina García S, et al. Urbanization causes biotic homogenization of woodland bird communities at multiple spatial scales. Global Change Biology, 2022, 28: 6152-6164
[35] Reis E, López-Iborra GM, Pinheiro RT. Changes in bird species richness through different levels of urbanization: Implications for biodiversity conservation and garden design in Central Brazil. Landscape and Urban Planning, 2012, 107: 31-42
[36] Dale S. Urban bird community composition influenced by size of urban green spaces, presence of native forest, and urbanization. Urban Ecosystems, 2018, 21: 1-14
[37] Snep RPH, Kooijmans JL, Kwak RGM, et al. Urban bird conservation: Presenting stakeholder-specific arguments for the development of bird-friendly cities. Urban Ecosystems, 2016, 19: 1535-1550
[38] Morelli F, Benedetti Y, Ibáñez-Álamo JD, et al. Evidence of evolutionary homogenization of bird communities in urban environments across Europe. Global Ecology and Biogeography, 2016, 25: 1284-1293
[39] Brouwer L, de Vries EHJ, Sierdsema H, et al. A country-wide examination of effects of urbanization on common birds. Animal Conservation, 2024, 27: 698-709
[40] Partridge DR, Clark JA. Small urban green roof plots near larger green spaces may not provide additional habitat for birds. Frontiers in Ecology and Evolution, 2022, 10: 779005
[41] Meffert PJ, Dziock F. The influence of urbanisation on diversity and trait composition of birds. Landscape Eco-logy, 2013, 28: 943-957
[42] Rodrigues AG, Borges-Martins M, Zilio F. Bird diversity in an urban ecosystem: The role of local habitats in understanding the effects of urbanization. Iheringia Série Zoologia, 2018, 108: e2018017
[43] Buxton VL, Benson TJ. Conservation-priority grassland bird response to urban landcover and habitat fragmentation. Urban Ecosystems, 2016, 19: 599-613
[44] Charre GM, Hurtado JAZ, Néve G, et al. Relationship between habitat traits and bird diversity and composition in selected urban green areas of Mexico City. Ornitologia Neotropical, 2013, 24: 279-297
[45] Filippi-Codaccioni O, Devictor V, Clobert J, et al. Effects of age and intensity of urbanization on farmland bird communities. Biological Conservation, 2008, 141: 2698-2707
[46] Leveau LM, Leveau CM. The role of urbanization and seasonality on the temporal variability of bird communities. Landscape and Urban Planning, 2012, 106: 271-276
[47] Ramírez-Albores JE, Sánchez-González LA, Pérez-Suárez M, et al. Greenspaces as shelters for the conservation of bird diversity in a big city. Urban Ecosystems, 2024, 27: 2047-2059
[48] 住房和城乡建设部. 住房城乡建设部关于印发国家园林城市系列标准及申报评审管理办法的通知. (2016-10-28) [2025-11-28]. https://www.mohurd.gov.cn
[49] Li DL, Chen SH, Lloyd HUW, et al. The importance of artificial habitats to migratory waterbirds within a natural/artificial wetland mosaic, Yellow River Delta, China. Bird Conservation International, 2013, 23: 184-198
[50] Wang YP, Ding P, Chen SH, et al. Nestedness of bird assemblages on urban woodlots: Implications for conservation. Landscape and Urban Planning, 2013, 111: 59-67
[51] 毛志滨, 郝日明. 观果树种配植与城市鸟类生物多样性保护. 江苏林业科技, 2005, 32(1): 11-13
[52] Yin LQ, Wang C, Han WJ, et al. Birds’ flight initiation distance in residential areas of Beijing are lower than in pristine environments: Implications for the conservation of urban bird diversity. Sustainability, 2023, 15: 4994
[53] Yuan KQ, Yang S, Liu JP, et al. Responses of birds to observers holding popguns: Hunting history influences escape behavior of urban birds. Current Zoology, 2024, 70: 631-636
[54] 张皖清. 北京奥林匹克森林公园鸟类栖息地植物景观研究. 硕士论文. 北京: 北京林业大学, 2015
[55] Yu TL, Guo YS. Effects of urbanization on bird species richness and community composition. Pakistan Journal of Zoology, 2013, 45: 59-69
[56] Tsiakiris R, Stara K, Pantis J, et al. Microhabitat selection by three common bird species of montane farmlands in northern Greece. Environmental Management, 2009, 44: 874-887
[57] Zhou DQ, Chu LM. How would size, age, human disturbance, and vegetation structure affect bird communities of urban parks in different seasons? Journal of Ornithology, 2012, 153: 1101-1112
[58] Chen XM, Zhang Q, Lan SS, et al. Nest predation pressure on Chinese bulbuls decreases along the urbanization gradient in Hangzhou, China. Avian Research, 2022, 13: 100049
[59] 刘巷序. 城市绿地景观结构特征对鸟类群落的影响. 博士论文. 上海: 华东师范大学, 2023
[60] 李海萍, 王娜萍, 代宇庭. 不同强度人类活动下拉市海鸟类密度分布研究. 湿地科学, 2021, 19(2): 162-169
[61] Callaghan CT, Chase JM, McGlinn DJ. Anthropogenic habitat modification causes nonlinear multiscale bird diversity declines. Ecography, 2024, 2024: e06759
[62] Sadam A, Khan RU, Mahmood S, et al. Spatial distribution and diversity of bird communities in District Mardan, Khyber Pakhtunkhwa, Pakistan. Pakistan Journal of Zoology, 2022, 54: 745-750
[63] Saulnier A, Bleu J, Boos A, et al. Inter-annual variation of physiological traits between urban and forest great tits. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology, 2023, 279: 111385
[64] Neumann AE, Suarez-Rubio M, Renner SC. Haemosporidian intensity and nestlings’ life-history along an urban-to-rural gradient. Scientific Reports, 2024, 14: 17018
[65] Prestes TV, Manica LT, de Guaraldo AC. Behavioral responses of urban birds to human disturbance in urban parks at Curitiba, Paraná (Brazil). Revista Brasileira de Ornitologia, 2018, 26: 77-81
[66] Tätte K, Møller AP, Mänd R. Towards an integrated view of escape decisions in birds: Relation between flight initiation distance and distance fled. Animal Behaviour, 2018, 136: 75-86
[67] Carlen EJ, Li R, Winchell KM. Urbanization predicts flight initiation distance in feral pigeons (Columba livia) across New York City. Animal Behaviour, 2021, 178: 229-245
[68] Merrall ES, Evans KL. Anthropogenic noise reduces avian feeding efficiency and increases vigilance along an urban-rural gradient regardless of species’ tolerances to urbanisation. Journal of Avian Biology, 2020, 51: 02341
[69] Luther DA, Phillips J, Derryberry EP. Not so sexy in the city: Urban birds adjust songs to noise but compromise vocal performance. Behavioral Ecology, 2016, 27: 332-340
[70] De Magalhães Tolentino VC, Baesse CQ, de Melo C. Dominant frequency of songs in tropical bird species is higher in sites with high noise pollution. Environmental Pollution, 2018, 235: 983-992
[71] Clement MA, Barrett K, Baldwin RF. Key habitat features facilitate the presence of Barred Owls in developed landscapes. Avian Conservation & Ecology, 2019, 14: 12
[72] Palma A, Blas J, Tella JL, et al. Differences in adrenocortical responses between urban and rural burrowing owls: Poorly-known underlying mechanisms and their implications for conservation. Conservation Physiology, 2020, 8: coaa054
[73] Becker DJ, Teitelbaum CS, Murray MH, et al. Asses-sing the contributions of intraspecific and environmental sources of infection in urban wildlife: Salmonella enterica and white ibis as a case study. Journal of the Royal Society Interface, 2018, 15: 20180654
[74] Iqbal F, Ayub Q, Wilson R, et al. Monitoring of heavy metal pollution in urban and rural environments across Pakistan using House crows (Corvus splendens) as bioindicator. Environmental Monitoring and Assessment, 2021, 193: 1-16
[75] Sándor K, Liker A, Sinkovics C, et al. Urban nestlings have reduced number of feathers in great tits (Parus major). Ibis, 2021, 163: 1369-1378
[76] Ellis JL, Ponette-González AG, Fry M, et al. Reduced reflectance and altered color: The potential cost of external particulate matter accumulation on urban rock pigeon (Columba livia) feathers. Frontiers in Ecology and Evolution, 2023, 11: 946624
[77] 王茜, 刘智存, 刘天宇, 等. 城市鸟类多样性研究中的多维度探索研究进展. 生态学杂志, 2022, 41(10): 2058-2063
[78] Chace JF, Walsh JJ. Urban effects on native avifauna: A review. Landscape and Urban Planning, 2006, 74: 46-69
[79] Zhou DQ, Fung T, Chu LM. Avian community structure of urban parks in developed and new growth areas: A landscape-scale study in Southeast Asia. Landscape and Urban Planning, 2012, 108: 91-102
[80] Walcott CF. Changes in bird life in Cambridge, Massachusetts from 1860 to 1964. The Auk, 1974, 91: 151-160
[81] 赵欣如, 房继明, 宋杰, 等. 北京的公园鸟类群落结构研究. 动物学杂志, 1996, 31(3): 17-21
[82] Xu X, Xie YJ, Qi K, et al. Detecting the response of bird communities and biodiversity to habitat loss and fragmentation due to urbanization. Science of the Total Environment, 2018, 624: 1561-1576
[83] 郭诗怡, 斋藤馨, 夏原由博, 等. 城市建成环境对鸟类多样性的影响机制研究评述及展望. 中国园林, 2022, 38(2): 71-76
[84] Feng MLE, Che-Castaldo J. Comparing the reliability of relative bird abundance indices from standardized surveys and community science data at finer resolutions. PLoS One, 2021, 16: e0257226
[85] 庄艳美. 城市绿地空间格局对鸟类群落影响研究. 硕士论文. 南京: 南京大学, 2015
[86] 游巍斌, 蔡新瑜, 王英姿, 等. 基于不同网格尺度福州主城区鸟类多样性与景观特征的关系研究. 生态学报, 2023, 43(18): 7670-7681
[87] 陈锦云, 周立志. 安徽沿江浅水湖泊越冬水鸟群落的集团结构. 生态学报, 2011, 31(18): 5323-5331
[88] 张晶, 赵成章, 任悦, 等. 张掖国家湿地公园优势鸟类种群生态位研究. 生态学报, 2018, 38(6): 2213-2220
[89] 曹长雷, 韩宗先, 李宏群, 等. 城市化对涪陵三峡库区城市鸟类群落结构的影响. 安徽农业科学, 2010, 38(3): 1275-1278
[90] 郭佳. 北京市区公园鸟类群落及其栖息地研究. 硕士论文. 北京: 北京林业大学, 2008
[91] 隋金玲, 李凯, 胡德夫, 等. 城市化和栖息地结构与鸟类群落特征关系研究进展. 林业科学, 2004, 40(6): 147-152
[92] Blair RB. Birds and butterflies along an urban gradient: Surrogate taxa for assessing biodiversity? Ecological Applications, 1999, 9: 164-170
[93] Leveau LM, Isla FI, Bellocq MI. Urbanization and the temporal homogenization of bird communities: A case study in central Argentina. Urban Ecosystems, 2015, 18: 1461-1476
[94] McKinney ML. Urbanization as a major cause of biotic homogenization. Biological Conservation, 2006, 127: 247-260
[95] Devictor V, Julliard R, Clavel J, et al. Functional biotic homogenization of bird communities in disturbed landscapes. Global Ecology and Biogeography, 2008, 17: 252-261
[96] 蒋涛, 姜琳琳, 解晋敏, 等. 基于兴趣点数据和最大熵模型的苏州市鸟类多样性研究. 生态与农村环境学报, 2024, 40(11): 1473-1484
[97] 杨雪如. 南京城市公园鸟类多样性及其影响因素. 硕士论文. 南京: 南京师范大学, 2022
[98] 姚雨欣. 浙江农林大学东湖校区鸟类多样性及栖息地调查研究. 硕士论文. 杭州: 浙江农林大学, 2023
[99] Farina A. Landscape structure and breeding bird distribution in a sub-Mediterranean agro-ecosystem. Landscape Ecology, 1997, 12: 365-378
[100] 陈水华, 丁平, 郑光美, 等. 岛屿栖息地鸟类群落的丰富度及其影响因子. 生态学报, 2002, 22(2): 141-149
[101] Khera N, Mehta V, Sabata BC. Interrelationship of birds and habitat features in urban greenspaces in Delhi, India. Urban Forestry & Urban Greening, 2009, 8: 187-196
[102] Fernández-Juricic E. Bird community composition patterns in urban parks of Madrid: The role of age, size and isolation. Ecological Research, 2000, 15: 373-383
[103] 谢世林. 北京城区公园繁殖期鸟类群落特征及多尺度影响因素研究. 硕士论文. 合肥: 中国科学技术大学, 2017
[104] 邓娇, 晏玉莹, 张志强, 等. 城市化对长沙市区城市公园繁殖期鸟类物种多样性的影响. 生态学杂志, 2014, 33(7): 1853-1859
[105] Angelstam P, Roberge JM, Lõhmus A, et al. Habitat modelling as a tool for landscape-scale conservation: A review of parameters for focal forest birds. Ecological Bulletins, 2004, 51: 427-453
[106] Sandström UG, Angelstam P, Mikusiński G. Ecological diversity of birds in relation to the structure of urban green space. Landscape and Urban Planning, 2006, 77: 39-53
[107] Castano-Villa GJ, Estevez JV, Guevara G, et al. Differential effects of forestry plantations on bird diversity: A global assessment. Forest Ecology and Management, 2019, 440: 202-207
[108] Lewandowski P, Przepióra F, Ciach M. Single dead trees matter: Small-scale canopy gaps increase the species richness, diversity and abundance of birds breeding in a temperate deciduous forest. Forest Ecology and Management, 2021, 481: 118693
[109] 毕骄. 城市公园绿地植被结构与鸟类多样性关系研究. 硕士论文. 杨凌: 西北农林科技大学, 2019
[110] 陈颖媛. 不同植被结构校园绿地中鸟类群落组成、垂直分布、行为及关系研究. 硕士论文. 杨凌: 西北农林科技大学, 2023
[111] Emlen JT. An urban bird community in Tucson, Arizona: Derivation, structure, regulation. The Condor, 1974, 76: 184-197
[112] 王春晓, 何建华, 刘殿锋, 等. 土地利用变化对鸟类栖息地连通性的影响: 以鄂州市为例. 生态学报, 2022, 42(10): 4197-4208
[113] Sodhi NS, Briffett C, Kong L, et al. Bird use of linear areas of a tropical city: Implications for park connector design and management. Landscape and Urban Planning, 1999, 45: 123-131
[114] 李晓文, 胡远满, 肖笃宁. 景观生态学与生物多样性保护. 生态学报, 1999, 19(3): 111-119
[115] Gillies CS, Beyer HL, St. Clair CC. Fine-scale movement decisions of tropical forest birds in a fragmented landscape. Ecological Applications, 2011, 21: 944-954
[116] 杨锡涛. 粤港澳大湾区水鸟生态廊道识别与生态廊道滨海区域营建模式研究. 博士论文. 哈尔滨: 东北林业大学, 2023
[117] Lin T, Coppack T, Lin QX, et al. Does avian flight initiation distance indicate tolerance towards urban disturbance? Ecological Indicators, 2012, 15: 30-35
[118] Vincze E, Bókony V, Garamszegi LZ, et al. Consistency and plasticity of risk-taking behaviour towards humans at the nest in urban and forest great tits, Parus major. Animal Behaviour, 2021, 179: 161-172
[119] Møller AP. Flight distance of urban birds, predation, and selection for urban life. Behavioral Ecology and Sociobiology, 2008, 63: 63-75
[120] Carrete M, Tella JL. Inter-individual variability in fear of humans and relative brain size of the species are rela-ted to contemporary urban invasion in birds. PLoS One, 2011, 6: e18859
[121] 田北辰, 李沛权, 黄千杜. 基于鸟类视角的城市生态廊道构建方法研究综述. 应用生态学报, 2021, 32(8): 3010-3022
[122] Bateman PW, Fleming PA. Who are you looking at? Hadeda ibises use direction of gaze, head orientation and approach speed in their risk assessment of a potential predator. Journal of Zoology, 2011, 285: 316-323
[123] Legagneux P, Ducatez S. European birds adjust their flight initiation distance to road speed limits. Biology Letters, 2013, 9: 20130417
[124] Díaz M, Møller AP, Flensted-Jensen E, et al. The geography of fear: A latitudinal gradient in anti-predator escape distances of birds across Europe. PLoS One, 2013, 8: e64634
[125] Dominoni DM, Halfwerk W, Baird E, et al. Why conservation biology can benefit from sensory ecology. Nature Ecology & Evolution, 2020, 4: 502-511
[126] Meillère A, Brischoux F, Angelier F. Impact of chronic noise exposure on antipredator behavior: An experiment in breeding house sparrows. Behavioral Ecology, 2015, 26: 569-577
[127] Wang YP, Chen SH, Blair RB, et al. Nest composition adjustments by Chinese bulbuls Pycnonotus sinensis in an urbanized landscape of Hangzhou (E China). Acta Ornithologica, 2009, 44: 185-192
[128] Lack D. The numbers of bird species on islands. Bird Study, 1969, 16: 193-209
[129] Scharper SB, Leman-Stefanovic I. The Natural City: Re-Envisioning the Built Environment. Toronto: University of Toronto Press, 2012: 11-35
[130] Wang YP, Huang Q, Lan SS, et al. Common blackbirds Turdus merula use anthropogenic structures as nesting sites in an urbanized landscape. Current Zoology, 2015, 61: 435-443
[131] Wang YP, Chen SH, Jiang PP, et al. Black-billed magpies (Pica pica) adjust nest characteristics to adapt to urbanization in Hangzhou, China. Canadian Journal of Zoology, 2008, 86: 676-684
[132] Chen XM, Zhang Q, Lan SS, et al. Variation in reproductive life-history traits of Chinese Bulbuls (Pycnonotus sinensis) along the urbanization gradient in Hangzhou, China. Avian Research, 2023, 14: 100100
[133] Crino OL, Johnson EE, Blickley JL, et al. Effects of experimentally elevated traffic noise on nestling white-crowned sparrow stress physiology, immune function and life history. Journal of Experimental Biology, 2013, 216: 2055-2062
[134] 蓝方源, 马行健, 逯金瑶, 等. 城市化对鸟类筑巢的影响研究综述. 生物多样性, 2021, 29(11): 1539-1553
[135] Chen XM, Zhang Q, Lan SS, et al. Anthropogenic nesting materials and reproductive performance of Chinese Bulbuls (Pycnonotus sinensis) along the urbanization gradient in Hangzhou, China. Avian Research, 2024, 15: 100207
[136] 李鹏, 张竞成, 李必成, 等. 城市化对杭州市鸟类营巢集团的影响. 动物学研究, 2009, 30(3): 295-302
[137] 毛齐正, 马克明, 邬建国, 等. 城市生物多样性分布格局研究进展. 生态学报, 2013, 33(4): 1051-1064
[138] 李乐, 张雷, 殷江霞, 等. 人工巢箱条件下两种山雀鸟类的同域共存机制. 生态学报, 2013, 33(1): 150-158
[139] Goodnow ML, Reitsma LR. Nest-site selection in the Canada Warbler (Wilsonia canadensis) in central New Hampshire. Canadian Journal of Zoology, 2011, 89: 1172-1177
[140] Ding ZH, Guo A, Lian M, et al. Landscape factors influencing bird nest site selection in urban green spaces. Frontiers in Ecology and Evolution, 2023, 11: 1258185
[141] Shochat E. Credit or debit? Resource input changes population dynamics of city-slicker birds. Oikos, 2004, 106: 622-626
[142] Liker A, Papp Z, Bókony V, et al. Lean birds in the city: Body size and condition of house sparrows along the urbanization gradient. Journal of Animal Ecology, 2008, 77: 789-795
[143] Amiot C, Harmange C, Ji W. Morphological differences along a chronological gradient of urbanisation in an endemic insectivorous bird of New Zealand. Urban Ecosystems, 2022, 25: 465-475
[144] Hüppi E, Geiger M. Fast-paced city life? Tempo and mode of phenotypic changes in urban birds from Switzerland. Ecology and Evolution, 2022, 12: e9217
[145] Skórka P, Grzywacz B, Bełcik M, et al. Environmental and social correlates of the plumage color polymorphism in an urban dweller, feral pigeon (Columba livia f. domestica). Scientific Reports, 2024, 14: 31400
[146] Chatelain M, Gasparini J, Frantz A. Do trace metals select for darker birds in urban areas? An experimental exposure to lead and zinc. Global Change Biology, 2016, 22: 2380-2391
[147] Leveau LM, Ibáñez I. Nesting site and plumage color are the main traits associated with bird species presence in urban areas. Animals, 2022, 12: 1148
[148] Leveau LM. Urbanization induces bird color homogenization. Landscape and Urban Planning, 2019, 192: 103645
[149] Partecke J, Schwabl I, Gwinner E. Stress and the city: Urbanization and its effects on the stress physiology in European blackbirds. Ecology, 2006, 87: 1945-1952
[150] Zhang SP, Lei FM, Liu SL, et al. Variation in baseline corticosterone levels of tree sparrow (Passer montanus) populations along an urban gradient in Beijing, China. Journal of Ornithology, 2011, 152: 801-806
[151] Dominoni DM, Goymann W, Helm B, et al. Urban-like night illumination reduces melatonin release in European blackbirds (Turdus merula): Implications of city life for biological time-keeping of songbirds. Frontiers in Zoology, 2013, 10: 1-11
[152] Jiang JX, He Y, Kou HH, et al. The effects of artificial light at night on Eurasian tree sparrow (Passer montanus): Behavioral rhythm disruption, melatonin suppression and intestinal microbiota alterations. Ecological Indicators, 2020, 108: 105702
[153] Whelan CJ, Wenny DG, Marquis RJ. Ecosystem ser-vices provided by birds. Annals of the New York Aca-demy of Sciences, 2008, 1134: 25-60
[154] Cid FD, Fernández NC, Pérez-Chaca MV, et al. House sparrow biomarkers as lead pollution bioindicators: Evaluation of dose and exposition length on hematological and oxidative stress parameters. Ecotoxicology and Environmental Safety, 2018, 154: 154-161
[155] Johnstone CP, Lill A, Reina RD. Use of erythrocyte indicators of health and condition in vertebrate ecophysio-logy: A review and appraisal. Biological Reviews, 2017, 92: 150-168
[156] Møller AP. Successful city dwellers: A comparative study of the ecological characteristics of urban birds in the Western Palearctic. Oecologia, 2009, 159: 849-858
[157] Merrill L, Stewart Merrill TE, Barger AM, et al. Avian health across the landscape: Nestling immunity covaries with changing landcover. Integrative and Comparative Biology, 2019, 59: 1150-1164
[158] Marzluff JM, Bowman R, Donnelly R. Avian Ecology and Conservation in an Urbanizing World. New York: Springer, 2001: 19-47
[159] Moreno-Mateos D, Power ME, Comín FA, et al. Structural and functional loss in restored wetland ecosystems. PLoS Biology, 2012, 10: e1001247
[160] 叶斯华, 张晓勉, 刘宝权. 香港米埔湿地的“保护经”. 浙江林业, 2016(2): 12-13
[161] Luan B, Liu Y, Che D, et al. Exploring nature-based solutions on refined waterbird habitats restoration in high-density urban area: A case study of the Futian Mangrove National Important Wetland in Shenzhen, China. Landscape Architecture Frontiers, 2024, 12: 36-52
[162] 夏心怡, 覃盟琳, 何淼, 等. 基于鸟类栖息地营建的城市湿地公园景观设计: 以佳木斯柳树岛为例. 野生动物学报, 2024, 45(1): 118-126
[163] 李晖, 刘彦, 黄伊琳, 等. 基于Maxent模型的深圳湾鸟类热点生境判别及修复研究. 中国园林, 2022, 38(12): 14-19
[164] Luo K, Wu ZL, Bai HT, et al. Bird diversity and waterbird habitat preferences in relation to wetland restoration at Dianchi Lake, south-west China. Avian Research, 2019, 10: 21
[165] Bennett AF. Linkages in the Landscape: The Role of Corridors and Connectivity in Wildlife Conservation. Cambridge: IUCN, 1998: 153-174
[166] Chen YX, Rasool MA, Hussain S, et al. Bird community structure is driven by urbanization level, blue-green infrastructure configuration and precision farming in Taizhou, China. Science of the Total Environment, 2023, 859: 160096
[167] Dondina O, Orioli V, Colli L, et al. Ecological network design from occurrence data by simulating species perception of the landscape. Landscape Ecology, 2018, 33: 275-287
[168] Lv ZY, Yang J, Wielstra B, et al. Prioritizing green spaces for biodiversity conservation in Beijing based on habitat network connectivity. Sustainability, 2019, 11: 2042
[169] Loss SR, Will T, Marra PP. Direct mortality of birds from anthropogenic causes. Annual Review of Ecology, Evolution, and Systematics, 2015, 46: 99-120
[170] Swaddle JP, Emerson LC, Thady RG, et al. Ultraviolet-reflective film applied to windows reduces the likelihood of collisions for two species of songbird. PeerJ, 2020, 8: e9926
[171] 戎灿中, 谢恺琪, 尹玉柱. 城市公园防鸟撞工作的初步实践. 动物学杂志, 2024, 59(4): 520-526
[172] Klem Jr D. Collisions between birds and windows: Mortality and prevention. Journal of Field Ornithology, 1990: 120-128
[173] van Doren BM, Horton KG, Dokter AM, et al. High-intensity urban light installation dramatically alters nocturnal bird migration. Proceedings of the National Aca-demy of Sciences of the United States of America, 2017, 114: 11175-11180
[174] 陈心虹. 鸟类生境需求的城市公园植物配置研究. 硕士论文. 广州: 仲恺农业工程学院, 2021
[175] 陈煜. 鸟类多样性视角下城市公园绿地生境提升策略研究. 硕士论文. 南京: 南京林业大学, 2023
[176] 王洪昌, 夏舫, 张渊媛, 等. 基于深度学习算法的鸟类及其栖息地识别: 以北京翠湖国家城市湿地公园为例. 生态学杂志, 2024, 43(7): 2231-2238
[177] 朱淑怡, 段菲, 李晟. 基于红外相机网络促进我国鸟类多样性监测: 现状、问题与前景. 生物多样性, 2017, 25(10): 1114-1122
[178] 李清荣. 基于深度学习的城市森林公园鸟声识别方法研究. 硕士论文. 广州: 广州大学, 2023
[179] Nor ANM, Corstanje R, Harris JA, et al. Ecological connectivity networks in rapidly expanding cities. He-liyon, 2017, 3: e00325
[180] Luna Á, Blanch E. Seasonal diversity, daily use and behaviour of birds using a green roof in a Mediterranean city. Royal Society Open Science, 2024, 11: 240761
[181] Caorsi V, Sprau P, Zollinger SA, et al. Nocturnal res-ting behaviour in urban great tits and its relation to anthropogenic disturbance and microclimate. Behavioral Ecology and Sociobiology, 2019, 73: 1-9
[182] Basile M, Russo LF, Russo VG, et al. Birds seen and not seen during the COVID-19 pandemic: The impact of lockdown measures on citizen science bird observations. Biological Conservation, 2021, 256: 109079
[183] Jedlicka JA, Greenberg R, Letourneau DK. Avian conservation practices strengthen ecosystem services in California vineyards. PLoS One, 2011, 6: e27347
[184] Methorst J. Positive relationship between bird diversity and human mental health: An analysis of repeated cross-sectional data. The Lancet Planetary Health, 2024, 8: e285-e296
[185] Steven R, Morrison C, Castley JG. Birdwatching and avitourism: A global review of research into its participant markets, distribution and impacts, highlighting future research priorities to inform sustainable avitou-rism management. Journal of Sustainable Tourism, 2015, 23: 125-144