Assessing the regional climate connectivity based on climate trajectory simulation: A case study of Zhangjiakou City, Hebei Province, China

doi:10.13287/j.1001-9332.202510.022

Abstract

Abstract: Climate change and human disturbances increasingly impede species migration and exacerbate the global biodiversity crisis. However, current research on the fine-scale climate connectivity remained limited and insufficient to effectively guide the construction of climate corridors. With Zhangjiakou in Hebei Province as a case, we employed climate exposure cost, human exposure cost, and minimum cumulative exposure models to simulate climate trajectories from 2004 to 2080, and assessed climate connectivity under compound climate-human stress. The results showed that topographic heterogeneity was the dominant factor driving the spatial variation in exposure costs, leading to compound exposure costs in the study area shifting from high in the south, low in the north to high in the north, low in the south as the species’ thermal tolerance threshold increased. Climate connectivity across Zhangjia-kou was generally low. The Bashang Plateau and the Taihang Mountains served as potential source and sink areas for regional species migration, respectively. Meanwhile, human disturbance significantly suppressed climate connectivity, with the Bashang Plateau being the most strongly affected. In the future, species would be expected to migrate mainly along the “Bashang-Taihang Mountains” pathway, but gaps in local climatic niches may restrict species movement. In the future, it is necessary to assess climate connectivity at multiple spatial scales, in alignment with conservation goals and species-specific traits. Finally, we proposed multiple strategies for climate corridor construction, such as adjusting corridor paths along climate gradients and designing corridor widths based on the biological characteristics of species.

Key words: climate connectivity, climate trajectory, climate corridor, climate change, human disturbance, species migration

XUE Qiannan, SHI Mingxi, WANG Yingying, LIU Xueqi, WANG Lu, LI Hao. Assessing the regional climate connectivity based on climate trajectory simulation: A case study of Zhangjiakou City, Hebei Province, China[J]. Chinese Journal of Applied Ecology, 2025, 36(10): 3139-3149.

References

[1] Su J, Kong FH, Yin HW, et al. Essential contribution of habitats in non-protected areas to climate-driven species migration in China. Geography and Sustainability, 2025, 6: 100203
[2] Dobrowski SZ, Littlefield CE, Lyons DS, et al. Protected-area targets could be undermined by climate change-driven shifts in ecoregions and biomes. Communications Earth & Environment, 2021, 2: 198
[3] McGuire JL, Lawler JJ, McRae BH, et al. Achieving climate connectivity in a fragmented landscape. Procee-dings of the National Academy of Sciences of the United States of America, 2016, 113: 7195-7200
[4] Parks SA, Carroll C, Dobrowski SZ, et al. Human land uses reduce climate connectivity across North America. Global Change Biology, 2020, 26: 2944-2955
[5] Keeley ATH, Ackerly DD, Cameron DR, et al. New concepts, models, and assessments of climate-wise connectivity. Environmental Research Letters, 2018, 13: 073002
[6] Hilty J, Worboys GL, Keeley A, et al. Guidelines for Conserving Connectivity through Ecological Networks and Corridors. Gland, Switzerland: IUCN, 2020
[7] Loarie SR, Duffy PB, Hamilton H, et al. The velocity of climate change. Nature, 2009, 462: 1052-1055
[8] Carroll C, Parks SA, Dobrowski SZ, et al. Climatic, topographic, and anthropogenic factors determine connectivity between current and future climate analogs in North America. Global Change Biology, 2018, 24: 5318-5331
[9] Carroll C, Roberts DR, Michalak JL, et al. Scale-dependent complementarity of climatic velocity and environmental diversity for identifying priority areas for conservation under climate change. Global Change Biology, 2017, 23: 4508-4520
[10] Hamann A, Roberts DR, Barber QE, et al. Velocity of climate change algorithms for guiding conservation and management. Global Change Biology, 2015, 21: 997-1004
[11] Gougherty AV, Prasad AM, Peters MP, et al. Climate change and the emergence of no-analog forest assemblages in North America. Global Change Biology, 2024, 30: e17605
[12] Burrows MT, Schoeman DS, Richardson AJ, et al. Geographical limits to species-range shifts are suggested by climate velocity. Nature, 2014, 507: 492-495
[13] Dobrowski SZ, Parks SA. Climate change velocity underestimates climate change exposure in mountainous regions. Nature Communications, 2016, 7: 12349
[14] Michalak JL, Stralberg D, Cartwright JM, et al. Combining physical and species-based approaches improves refugia identification. Frontiers in Ecology and the Environment, 2020, 18: 254-260
[15] Stralberg D, Carroll C, Nielsen SE. Toward a climate-informed North American protected areas network: Incorporating climate-change refugia and corridors in conservation planning. Conservation Letters, 2020, 13: e12712
[16] Parks SA, Holsinger LM, Abatzoglou JT, et al. Protected areas not likely to serve as stepping stones for species undergoing climate-induced range shifts. Global Change Biology, 2023, 29: 2681-2696
[17] Grantham HS, Duncan A, Evans TD, et al. Anthropogenic modification of forests means only 40% of remaining forests have high ecosystem integrity. Nature Communications, 2020, 11: 5978
[18] Hak JC, Comer PJ. Modeling landscape condition for biodiversity assessment: Application in temperate North America. Ecological Indicators, 2017, 82: 206-216
[19] Yang J, Xue QN, Li H, et al. Assessing comprehensive anthropogenic impacts at a regional scale using ecological integrity. Ecological Indicators, 2024, 167: 112738
[20] Venter O, Sanderson EW, Magrach A, et al. Sixteen years of change in the global terrestrial human footprint and implications for biodiversity conservation. Nature Communications, 2016, 7: 12558
[21] Watson JEM, Venter O. Mapping the continuum of humanity’s footprint on land. One Earth, 2019, 1: 175-180
[22] Woolmer G, Trombulak SC, Ray JC, et al. Rescaling the human footprint: A tool for conservation planning at an ecoregional scale. Landscape and Urban Planning, 2008, 87: 42-53
[23] Dijkstra EW. A note on two problems in connexion with graphs. Numerische Mathematik, 1959, 1: 269-271
[24] 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
[25] Carroll C, McRae BH, Brookes A. Use of linkage mapping and centrality analysis across habitat gradients to conserve connectivity of gray wolf populations in western North America. Conservation Biology, 2012, 26: 78-87
[26] Littlefield CE, McRae BH, Michalak JL, et al. Connecting today’s climates to future climate analogs to facilitate movement of species under climate change. Conservation Biology, 2017, 31: 1397-1408
[27] Senior RA, Hill JK, Edwards DP. Global loss of climate connectivity in tropical forests. Nature Climate Change, 2019, 9: 623-626
[28] Su J, Kong FH, Yin HW, et al. Past, present and future climate connectivity informs conservation strategies in the Yangtze River delta urban agglomeration, China. Landscape and Urban Planning, 2023, 240: 104894
[29] Han QY, Li M, Keeffe G. Can large-scale tree planting in China compensate for the loss of climate connectivity due to deforestation? Science of the Total Environment, 2024, 927: 172350
[30] 中华人民共和国自然资源部. 自然资源部办公厅关于印发《中国陆域生态基础分区(试行)》的通知[EB/OL]. (2023-05-16) [2024-11-10]. https://gi.mnr.gov.cn/202306/t20230614_2791436.html
[31] 中华人民共和国生态环境部. 生态环境部发布《中国生物多样性保护战略与行动计划(2023—2030年)》[EB/OL]. (2024-01-18) [2024-11-10]. https://www.mee.gov.cn/ywdt/hjywnews/202401/t20240118_1064111.shtml
[32] 薛倩楠, 王莹莹, 史明晰, 等. 张家口市生态完整性评估及其影响因素分析. 中国生态农业学报, 2024, 32(12): 2150-2161
[33] 李皓, 赵友, 薛倩楠, 等. 张家口市生态系统服务权衡与协同分区优化管理. 陆地生态系统与保护学报, 2023, 3(6): 10-22
[34] Peng S. 1-km Monthly Mean Temperature Dataset for China (1901-2023). National Tibetan Plateau / Third Pole Environment Data Center [EB/OL]. (2024-07-17) [2024-12-11]. https://data.tpdc.ac.cn/en/data/71ab4677-b66c-4fd1-a004-b2a541c4d5bf/
[35] Fick SE, Hijmans RJ. WorldClim 2: New 1-km spatial resolution climate surfaces for global land areas. International Journal of Climatology, 2017, 37: 4302-4315
[36] 中国气象局. 综合气象观测系统发展规划(2010—2015年)[EB/OL]. (2015-07-02) [2025-04-02]. https://www.cma.gov.cn/2011xzt/2015zt/20150702/2015070202/201507020203/201507/t20150702_2867-80.html
[37] IPCC. Climate Change 2023: Synthesis Report[EB/OL]. (2023-12-12) [2025-02-20]. https://www.ipcc.ch/report/ar6/syr/downloads/report/IPCC_AR6_SYR_SPM.pdf
[38] Parrish JD, Braun DP, Unnasch RS. Are we conserving what we say we are? Measuring ecological integrity within protected areas. BioScience, 2003, 53: 851-860
[39] Yang J, Huang X. The 30 m annual land cover dataset and its dynamics in China from 1990 to 2019. Earth System Science Data, 2021, 13: 3907-3925
[40] van Etten J. R package gdistance: Distances and routes on geographical grids. Journal of Statistical Software, 2017, 76: 1-21
[41] Burrows MT, Schoeman DS, Buckley LB, et al. The pace of shifting climate in marine and terrestrial ecosystems. Science, 2011, 334: 652-655
[42] Stralberg D, Carroll C, Nielsen SE. Toward a climate-informed North American protected areas network: Incorporating climate-change refugia and corridors in conservation planning. Conservation Letters, 2020, 13: e12712
[43] Hannah L, Flint L, Syphard AD, et al. Fine-grain mo-deling of species’ response to climate change: Holdouts, stepping-stones, and microrefugia. Trends in Eco-logy & Evolution, 2014, 29: 390-397
[44] 周颖, 冯喆, 林倩, 等. 生态安全格局中生态廊道宽度研究进展. 应用生态学报, 2025, 36(3): 918-926
[45] Rocha ÉGd, Brigatti E, Niebuhr BB, et al. Dispersal movement through fragmented landscapes: The role of stepping stones and perceptual range. Landscape Ecology, 2021, 36: 3249-3267
[46] Lun YR, Liu L, Cheng L, et al. Assessment of GCMs simulation performance for precipitation and temperature from CMIP5 to CMIP6 over the Tibetan Plateau. International Journal of Climatology, 2021, 41: 3994-4018
[47] Bennett JM, Sunday J, Calosi P, et al. The evolution of critical thermal limits of life on Earth. Nature Communications, 2021, 12: 1198
[48] 孙中宇, 陈燕乔, 杨龙, 等. 轻小型无人机低空遥感及其在生态学中的应用进展. 应用生态学报, 2017, 28(2): 528-536