基于CiteSpace的景观连通性研究文献计量分析

doi:10.11924/j.issn.1000-6850.casb2022-0872

摘要/Abstract

摘要：

随着气候变化和人类活动对景观格局及生态过程扰动的增强，关于景观连通性的研究越来越多，但缺乏系统的文献梳理，对其研究现状及前沿热点认识不足。基于Web of Science核心合集数据库检索的文献数据及文献计量学软件CiteSpace，对2000—2021年景观连通性研究的发文数量、发文学科、研究力量以及高被引文献等进行可视化分析。结果表明：（1）近20年来，该研究历经了缓慢发展、稳步增长和快速发展阶段，主要分布于生态学、环境科学和地理科学等学科。（2）中国科学院和北京师范大学发表了较多相关成果，大大提升了中国在此研究领域中的国际影响力。（3）景观连通性相关研究的基础内容主要包括探究生物物种扩散机制、自然保护区设计构建与生态网络规划、景观破碎化分析等。发展与应用景观连通性相关评估指标与模型是主要热点内容，从连通性角度开展泥沙输移过程的量化、生物多样性保护与生态系统服务功能评价、气候变化与人类活动双重影响下水文连通性多尺度效应评估是研究前沿。

关键词: 景观连通性, 连通性, 景观格局, 热点分析, 文献计量, CiteSpace软件

Abstract:

As the intensified climate change and rising stress from human activities on landscape patterns and landscape ecological processes, landscape connectivity research receives more and more attention worldwide. However, the relative research status and hotspots are still lack of systematic analysis. In this study, the number of papers, subject, study strength, and highly cited literature about landscape connectivity research from 2000 to 2021 were analyzed based on the Web of Science core collection database retrieval and the bibliometric software CiteSpace. The results showed that: (1) in the past 20 years, the research about landscape connectivity experienced the stages of slow development, steady growth and rapid development, and it was mainly distributed in ecology, environmental science and geographical science. (2) The Chinese Academy of Sciences and the Beijing Normal University published many achievements in relative journals, greatly enhancing China’s international influence in this research field. (3) There was some basic research on landscape connectivity, including the exploration of species diffusion mechanism, the design and planning of nature reserves and ecological network, the analysis of landscape fragmentation, etc. The hotspots were mainly focused on developing and applying the related indicators and models of landscape connectivity. The current research frontiers include the quantification of sediment transport process from the perspective of connectivity, biodiversity conservation and assessment of ecosystem services, and the evaluation about the multi-scale effects of hydrological connectivity under the combined influence of climate change and human activities.

Key words: landscape connectivity, connectivity, landscape pattern, research hotpots, bibliometrics, CiteSpace

边熇, 朱冰冰, 黎珩, 王蓉. 基于CiteSpace的景观连通性研究文献计量分析[J]. 中国农学通报, 2023, 39(31): 157-164.

BIAN He, ZHU Bingbing, LI Heng, WANG Rong. Bibliometric Analysis of Landscape Connectivity Research Based on CiteSpace[J]. Chinese Agricultural Science Bulletin, 2023, 39(31): 157-164.

图/表 9

参考文献 32

[1]	BROOKS C P. A scalar analysis of landscape connectivity[J]. Oikos, 2003, 102(2):433-439. doi: 10.1034/j.1600-0579.2003.11511.x URL
[2]	TAYLOR P D, FAHRIG L, HENEIN K, et al. Connectivity is a vital element of landscape structure[J]. Oikos, 1993, 68(3):571-573. doi: 10.2307/3544927 URL
[3]	BRACKEN L J, CROKE J. The concept of hydrological connectivity and its contribution to understanding runoff-dominated geomorphic systems[J]. Hydrological processes, 2007, 21(13):1749-1763. doi: 10.1002/hyp.v21:13 URL
[4]	ANTOINE M, JAVAUX M, BIELDERS C. What indicators can capture runoff-relevant connectivity properties of the micro-topography at the plot scale?[J]. Advances in water resources, 2009, 32(8):1297-1310. doi: 10.1016/j.advwatres.2009.05.006 URL
[5]	PRINGLE C M. Hydrologic connectivity and the management of biological reserves: A global perspective[J]. Ecological applications, 2001, 11(4):981-998. doi: 10.1890/1051-0761(2001)011[0981:HCATMO]2.0.CO;2 URL
[6]	陈悦, 陈超美, 刘则渊, 等. CiteSpace知识图谱的方法论功能[J]. 科学学研究, 2015, 33(2):242-253.
[7]	赵翔, 贺桂珍. 基于CiteSpace的驱动力-压力-状态-影响-响应分析框架研究进展[J]. 生态学报, 2021, 41(16):6692-6705.
[8]	赵蓉英, 许丽敏. 文献计量学发展演进与研究前沿的知识图谱探析[J]. 中国图书馆学报, 2010, 36(5):60-68.
[9]	BU H L, MCSHEA W J, WANG D J, et al. Not all forests are alike: the role of commercial forest in the conservation of landscape connectivity for the giant panda[J]. Landscape ecology, 2021, 36(9):2549-2564. doi: 10.1007/s10980-021-01262-2
[10]	ZHANG L Q, WANG H Z. Planning an ecological network of Xiamen Island (China) using landscape metrics and network analysis[J]. Landscape and urban planning, 2006, 78(4):449-456. doi: 10.1016/j.landurbplan.2005.12.004 URL
[11]	GUO Y Z, LIU Y Z. Connecting regional landscapes by ecological networks in the Greater Pearl River Delta[J]. Landscape and ecological engineering, 2017, 13(2):265-278. doi: 10.1007/s11355-016-0318-2 URL
[12]	杨红玉, 王明元, 游晓朝, 等. 植物共生信号的文献计量分析[J]. 生态学报, 2017, 37(14):4913-4918.
[13]	SPEAR S F, STORFER A. Landscape genetic structure of coastal tailed frogs (Ascaphus truei) in protected vs. managed forests[J]. Molecular ecology, 2008, 17(21):4642-4656. doi: 10.1111/j.1365-294X.2008.03952.x pmid: 19140987
[14]	COULON A, GUILLOT G, COSSON J F, et al. Genetic structure is influenced by landscape features: Empirical evidence from a roe deer population[J]. Molecular ecology, 2006, 15(6):1669-1679. pmid: 16629819
[15]	MINOR E S, LOOKINGBILL T R. A multiscale network analysis of protected-area connectivity for mammals in the United States[J]. Conservation biology, 2010, 24(6):1549-1558. doi: 10.1111/j.1523-1739.2010.01558.x pmid: 20666801
[16]	GUPTA A, DILKINA B, MORIN D J, et al. Reserve design to optimize functional connectivity and animal density[J]. Conservation biology, 2019, 33(5):1023-1034. doi: 10.1111/cobi.13369 pmid: 31209924
[17]	BRUDVIG L, DAMSCHEN E, HADDAD N, et al. The influence of habitat fragmentation on multiple plant-animal interactions and plant reproduction[J]. Ecology, 2015, 96(10):2669-2678. pmid: 26649388
[18]	CHIU M C, AO S C, HE F Z, et al. Elevation shapes biodiversity patterns through metacommunity-structuring processes[J]. Science of the total environment, 2020, 743:9140548.
[19]	STEVENS V M, VERKENNE C, VANDEWOESTIJNE S, et al. Gene flow and functional connectivity in the natterjack toad[J]. Molecular ecology, 2006, 15(9):2333-2344. pmid: 16842409
[20]	WALPOLE A A, BOWMAN J, MURRAY D L, et al. Functional connectivity of lynx at their southern range periphery in Ontario, Canada[J]. Landscape ecology, 2012, 27(5):761-773. doi: 10.1007/s10980-012-9728-1 URL
[21]	KOMPANIZARE M, PETRONE R M, SHAFII M, et al. Effect of climate change and mining on hydrological connectivity of surficial layers in the Athabasca Oil Sands Region[J]. Hydrological processes, 2018, 32(25):3698-3716. doi: 10.1002/hyp.v32.25 URL
[22]	FERNÁNDEZ C, FERNÁNDEZ-ALONSO J M, VEGA J A. Exploring the effect of hydrological connectivity and soil burn severity on sediment yield after wildfire and mulching[J]. Land degradation & development, 2020, 31(13):1611-1621. doi: 10.1002/ldr.v31.13 URL
[23]	KUFEL L, LEŚNICZUK S. Hydrological connectivity as most probable key driver of chlorophyll and nutrients in oxbow lakes of the Bug River (Poland)[J]. Limnologica, 2014, 46:94-98. doi: 10.1016/j.limno.2013.10.008 URL
[24]	DEMBKOWSKI D J, MIRANDA L E. Comparison of fish assemblages in two disjoined segments of an oxbow lake in relation to connectivity[J]. Transactions of the American fisheries society, 2011, 140(4):1060-1069. doi: 10.1080/00028487.2011.607044 URL
[25]	ZHOU X D, XU M Z, WANG Z Y, et al. Responses of macroinvertebrate assemblages to environmental variations in the river-oxbow lake system of the Zoige wetland (Bai River, Qinghai-Tibet Plateau)[J]. Science of the total environment, 2019, 659:150-160. doi: 10.1016/j.scitotenv.2018.12.310 URL
[26]	NAJAFI S, DRAGOVICH D, HECKMANN T, et al. Sediment connectivity concepts and approaches[J]. Catena, 2021, 196:30.
[27]	ZHAO G J, GAO P, TIAN P, et al. Assessing sediment connectivity and soil erosion by water in a representative catchment on the Loess Plateau, China[J]. Catena, 2020, 185:104284. doi: 10.1016/j.catena.2019.104284 URL
[28]	TAYLOR R J, MASSEY C, FULLER I C, et al. Quantifying sediment connectivity in an actively eroding gully complex, Waipaoa catchment, New Zealand[J]. Geomorphology, 2018, 307:24-37. doi: 10.1016/j.geomorph.2017.10.007 URL
[29]	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[J]. 生态学报, 2018, 38(6):2221-2228.
[30]	高玉琴, 肖璇, 丁鸣鸣, 等. 基于改进图论法的平原河网水系连通性评价[J]. 水资源保护, 2018, 34(1):18-23.
[31]	FRESSARD M, COSSART E. A graph theory tool for assessing structural sediment connectivity: Development and application in the Mercurey vineyards (France)[J]. Science of the total environment, 2019, 651:2566-2584. doi: 10.1016/j.scitotenv.2018.10.158 URL
[32]	MCRAE B H, BEIER P. Circuit theory predicts gene flow in plant and animal populations[J]. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104(50):19885-19890. doi: 10.1073/pnas.0706568104 pmid: 18056641

排序	数量/篇	学科类别	排序	数量/篇	学科类别
1	1938	ecology	6	452	water resources
2	1201	environmental sciences	7	288	marine & freshwater biology
3	752	geosciences，multidisciplinary	8	164	engineering, environmental
4	750	geography	9	128	limnology
5	746	biodiversity conservation	10	123	soil science

排序	数量/篇	学科类别	排序	数量/篇	学科类别
1	1938	ecology	6	452	water resources
2	1201	environmental sciences	7	288	marine & freshwater biology
3	752	geosciences，multidisciplinary	8	164	engineering, environmental
4	750	geography	9	128	limnology
5	746	biodiversity conservation	10	123	soil science

排序	出现频次	中介中心性	被引次数	国家
1	1481	0.07	58815	美国
2	445	0.07	19169	澳大利亚
3	445	0	19935	加拿大
4	396	0	4108	中国
5	378	0.03	12695	德国
6	375	0.37	14434	英国
7	363	0.28	10968	法国
8	346	0.23	11947	西班牙
9	245	0	7728	巴西
10	217	0.03	6070	意大利

排序	出现频次	中介中心性	被引次数	国家
1	1481	0.07	58815	美国
2	445	0.07	19169	澳大利亚
3	445	0	19935	加拿大
4	396	0	4108	中国
5	378	0.03	12695	德国
6	375	0.37	14434	英国
7	363	0.28	10968	法国
8	346	0.23	11947	西班牙
9	245	0	7728	巴西
10	217	0.03	6070	意大利

排序	发文机构	所在国家	出现频次	占比/%	排序	发文机构	所在国家	出现频次	占比/%
1	美国地质勘探局	美国	129	2.81	6	佛罗里达大学	美国	65	1.42
2	中国科学院	中国	127	2.77	7	北京师范大学	中国	63	1.37
3	美国林务局	美国	104	2.27	8	瑞典农业科学大学	瑞典	60	1.31
4	科罗拉多州立大学	美国	78	1.70	9	多伦多大学	加拿大	60	1.31
5	西班牙国家研究委员会	西班牙	72	1.57	10	格里菲斯大学	澳大利亚	57	1.24