中国城市草坪的杂草优势种组成及空间分布

doi:10.17520/biods.2024133

摘要/Abstract

摘要：

为深入探究中国城市的杂草物种组成、空间分布及其主要影响因素, 本研究选取我国98个市(县)的城市草坪杂草作为研究对象, 基于2002-2024年间相关文献分析, 运用Jaccard相似性指数对β多样性进行度量。结果表明: (1)城市草坪杂草优势种有208种, 隶属40科137属, 其中菊科植物占比最高(22.12%)。植物区系地理成分复杂, 世界广布科占据显著优势(共23科), 但在属水平上, 温带分布属的数量(57个)超过热带分布属(42个), 科、属两级热带/温带成分比分别为2.33和0.74。(2)入侵杂草有37种, 隶属11科, 以菊科、禾本科和豆科为主(共占59.46%), 其中恶意入侵种10种, 严重入侵种11种, 局部入侵种4种, 一般入侵种12种。(3)城市间杂草组成相似性普遍较低, 其差异性与β多样性理论相符, 主要受地理距离和气候条件的共同影响。研究结果可为后续城市草坪杂草的科学管理、生物多样性保护和城市可持续发展提供理论基础。

关键词: 杂草, 城市草坪, 优势种, 空间分布, Jaccard相似性指数

Abstract

Aims: This paper conducts a comprehensive review of literature from the past two decades, focusing on two primary objectives. First, it explores the composition of dominant weed species in urban lawns across China, including the types and characteristics of invasive weeds. Second, it investigates the key factors influencing the distribution and spread of weeds in urban lawns in China. This study aim to provide a theoretical foundation for the scientific management and control of weeds in urban lawns and help protect biodiversity and promote sustainable urban development. Additionally, these findings can support efforts at monitoring weed population dynamics to maintain ecological balance and enhance the health and sustainability of urban green spaces.

Methods: This study conducted a comprehensive review of the literature on urban lawn weeds in 98 cities across China between 2002 and 2024. A statistical analysis of the weed species identified in the literature was carried out after gathering information on dominant weed species, including their Chinese and Latin names, family and genus details, life forms, and flora. These data were used to determine the species, origin, degree, and route of invasion for invasive weeds. Furthermore, β-diversity was assessed using the Jaccard similarity index. The data for this study were sourced from the CNKI database, WANFANG DATA, and VIP database. Statistical analyses were performed using R and SPSS software. The correlation between invasive weed distribution and climatic factors was examined through a nonlinear relationship, and the primary climatic factors influencing the distribution of weed species in urban lawns were identified using redundancy analysis (RDA). Together, these methods enabled a deep exploration of the species composition, spatial distribution, and main influencing factors of urban weeds in China.

Results: (1) A total of 208 dominant weeds, spanning 40 families and 137 genera, were identified in urban lawns. The Compositae was the most prevalent in the literature, constituting 22.12% of the total. The geographical distribution of these flora is complex, with cosmopolitan families holding a significant advantage (23 families). However, at the genus level, the number of temperate distribution genera (57) surpassed that of tropical distribution genera (42), resulting in a tropical to temperate ratio of 2.33 and 0.74 at the family and genus levels, respectively. (2) A total of 37 species of invasive weeds were identified, belonging to 11 families, predominantly Compositae, Gramineae and Fabaceae (59.46%). This included 10 species of malicious invasive species, 11 species of serious invasive species, 4 species of local invasive species, and 12 species of general invasive species. The distribution of invasive weeds in southern China was notably concentrated. (3) The variation in weed composition among different cities aligns with the β-diversity theory, as variation was primarily influenced by geographical distance and climatic conditions.

Conclusion: Plants, particularly Compositae and Gramineae weeds, which are primarily annual and perennial herbs, hold a significant advantage over other species due to their widespread distribution. These plants demonstrate ecological adaptability and competitiveness in the ecological context of urban lawns. A considerable number of invasive weeds are present in these lawns, with some species exhibiting strong dispersal capabilities and posing serious threats to the existing ecological environment. These species are more concentrated in the southern region of the country, indicating that the area faces greater challenges in managing and preventing the spread of invasive weeds. The variation in weed composition between cities aligns with β-diversity theory which suggests species distribution is primarily influenced by geographical distance and climatic conditions. Future research should seek to more accurately assess the risk of invasive weed establishment and further investigate the mechanisms driving diffusion of dominant weeds. Considering the increased influence of global warming on ecosystem dynamics, it is essential to strengthen methods for predicting the distribution of dominant weeds, particularly non-native invasive species, and to conduct research on effective means of biological control. Additionally, a deep study of the life history of frequently occurring weeds is necessary to provide a scientific basis for effective prevention and control strategies.

Key words: weeds, urban lawns, dominant species, spatial distribution, Jaccard similarity index

何泽嵘, 叶鹏, 王舒婷, 关永鑫, 闫淑君, 洪心茹 (2025) 中国城市草坪的杂草优势种组成及空间分布. 生物多样性, 33, 24133. DOI: 10.17520/biods.2024133.

Zerong He, Peng Ye, Shuting Wang, Yongxin Guan, Shujun Yan, Xinru Hong (2025) Composition and spatial distribution of dominant weed species in urban lawns of China. Biodiversity Science, 33, 24133. DOI: 10.17520/biods.2024133.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2024133

https://www.biodiversity-science.net/CN/Y2025/V33/I1/24133

图/表 8

参考文献 44

[1]	An C, Zhuang YX, Zheng P, Lin YX, Yang CZ, Qin Y (2023) A checklist of vascular plants in Fujian Province, China. Biodiversity Science, 31, 22537. (in Chinese with English abstract) DOI
	[安昌, 庄怡雪, 郑平, 林彦翔, 杨成梓, 秦源 (2023) 福建省维管植物名录. 生物多样性, 31, 22537.] DOI
[2]	Chen YH, Zhang RJ, Zhang XX, Ren LL (2023) Progress and prospect on natural regionalization in China. Geography and Geo-Information Science, 39(1), 80-90, 119. (in Chinese with English abstract)
	[陈跃红, 张若婧, 张晓祥, 任立良 (2023) 中国自然区划研究进展与展望. 地理与地理信息科学, 39(1), 80-90, 119.]
[3]	Delavaux CS, Crowther TW, Bever JD, Weigelt P, Gora EM (2024) Mutualisms weaken the latitudinal diversity gradient among oceanic islands. Nature, 627, 335-339.
[4]	Deng TJ, Wen J, Xian ZH, Li H, Zeng DQ, Zhou HG (2004) Populations of city turf weeds in Guangxi and their occurrence. Plant Protection, 30(6), 61-63. (in Chinese with English abstract)
	[邓铁军, 文军, 贤振华, 黎桦, 曾东强, 周厚高 (2004) 广西城市草坪杂草的种群及发生调查. 植物保护, 30(6), 61-63.]
[5]	Ding YH (2013) Climate in China. Science Press, Beijing. (in Chinese)
	[丁一汇 (2013) 中国气候. 科学出版社, 北京.]
[6]	Fang YQ, Zhang XH, Wei HY, Wang DJ, Chen RD, Wang LK, Gu W (2021) Predicting the invasive trend of exotic plants in China based on the ensemble model under climate change: A case for three invasive plants of Asteraceae. Science of the Total Environment, 756, 143841.
[7]	Green JL, Ostling A (2003) Endemics-area relationships: The influence of species dominance and spatial aggregation. Ecology, 84, 3090-3097.
[8]	Hijmans RJ, Williams E, Vennes C (2011) Geosphere: Spherical Trigonometry for Geographic Applications. http://cran.r-project.org/web/packages=geosphere. (accessed on 2024-10-02)
[9]	He YZ, Huang WD, Zhao X, Lü P, Wang HH (2021) Review on the impact of climate change on plant diversity. Journal of Desert Research, 41(1), 59-66. (in Chinese with English abstract) DOI
	[何远政, 黄文达, 赵昕, 吕朋, 王怀海 (2021) 气候变化对植物多样性的影响研究综述. 中国沙漠, 41(1), 59-66.] DOI
[10]	Hu TY, Huang H, Guo SL, Fang F (2007) Niche characteristic of exotic weeds in suburb and the impacts on biodiversity. Guihaia, 27, 873-881. (in Chinese with English abstract)
	[胡天印, 黄华, 郭水良, 方芳 (2007) 城市郊区外来杂草生态位特点及对生物多样性影响研究. 广西植物, 27, 873-881.]
[11]	Jaccard P (1912) The distribution of the flora in the alpine zone. New Phytologist, 11, 37-50.
[12]	Ju RT, Li H, Shih CJ, Li B (2012) Progress of biological invasions research in China over the last decade. Biodiversity Science, 20, 581-611. (in Chinese with English abstract) DOI
	[鞠瑞亭, 李慧, 石正人, 李博 (2012) 近十年中国生物入侵研究进展. 生物多样性, 20, 581-611.] DOI
[13]	Knot P, Hrabe F, Hejduk S, Skladanka J, Kvasnovsky M, Hodulikova L, Caslavova I, Horky P (2017) The impacts of different management practices on botanical composition, quality, colour and growth of urban lawns. Urban Forestry & Urban Greening, 26, 178-183.
[14]	Li BH, Wang GQ, Liu XM, Xu X, Zhao BC (2022) Analysis of weed biodiversity and influencing factors in foxtail millet (Setaria italica L.) ﬁeld in Hebei Province. Journal of Hebei Agricultural University, 45(3), 34-40, 62. (in Chinese with English abstract)
	[李秉华, 王贵启, 刘小民, 许贤, 赵铂锤 (2022) 河北省谷田杂草群落生物多样性与影响因子. 河北农业大学学报, 45(3), 34-40, 62.] DOI
[15]	Li JY, Shi MZ, Guo YQ, Zheng LZ, Wu MX, Fu JW (2020) Species and distribution of invasive alien plants in farmland ecosystems of Fujian Province. Journal of Tropical and Subtropical Botany, 28, 547-556. (in Chinese with English abstract)
	[李建宇, 史梦竹, 郭燕青, 郑丽祯, 吴梅香, 傅建炜 (2020) 福建省农田生态系统外来入侵植物种类及其分布. 热带亚热带植物学报, 28, 547-556.]
[16]	Li XJ (2018) Main problems and management strategies of weeds in agricultural fields in China in recent years. Plant Protection, 44(5), 77-84. (in Chinese with English abstract)
	[李香菊 (2018) 近年我国农田杂草防控中的突出问题与治理对策. 植物保护, 44(5), 77-84.]
[17]	Liu MQ, Yang XF, Shi YM, Liu YW, Li XM, Liao WJ (2022) Effects of simulated acid rain on the competitive relationship between invasive Ambrosia artemisiifolia and its co-occurring indigenous forb Bidens bipinnata. Chinese Journal of Plant Ecology, 46, 932-940. (in Chinese with English abstract)
	[柳牧青, 杨小凤, 石钰铭, 刘雨薇, 李小蒙, 廖万金 (2022) 模拟酸雨对入侵植物豚草与伴生种鬼针草竞争关系的影响. 植物生态学报, 46, 932-940.] DOI
[18]	Liu XY, Zhao CL, Xu MS, Liang QM, Zhu XT, Li L, Yan ER (2019) Beta diversity of vascular plants and its drivers in sea-islands of Eastern China. Biodiversity Science, 27, 380-387. (in Chinese with English abstract) DOI
	[刘翔宇, 赵慈良, 许洺山, 梁启明, 朱晓彤, 李亮, 阎恩荣 (2019) 中国东部海岛维管植物的beta多样性及其驱动因素. 生物多样性, 27, 380-387.] DOI
[19]	Liu ZC, Han LB (2018) Research on ecological and climatic regionalization for turfgrass in China based on ArcGIS. Pratacultural Science, 35, 1030-1039. (in Chinese with English abstract)
	[刘卓成, 韩烈保 (2018) 基于ArcGIS的中国草坪生态气候区划研究. 草业科学, 35, 1030-1039.]
[20]	Luo YT, Wang ZM, Cui XL, Zhao LK, Wang JH, Luo YL (2019) The reproductive traits and invasiveness of Bidens pilosa var. radiata. Chinese Journal of Ecology, 38, 655-662. (in Chinese with English abstract)
	[罗娅婷, 王泽明, 崔现亮, 赵利坤, 王桔红, 罗银玲 (2019) 白花鬼针草的繁殖特性及入侵性. 生态学杂志, 38, 655-662.]
[21]	Ma JS, Li HR (2018) The Checklist of the Alien Invasive Plants in China. Higher Education Press, Beijing. (in Chinese)
	[马金双, 李惠茹 (2018) 中国外来入侵植物名录. 高等教育出版社, 北京.]
[22]	Oksanen J, Blanchet F, Kindt R, Legendre P, Minchin P, O’Hara R, Simpson G, Solymos P, Stevens M, Wagner H (2013) vegan: Community Ecology Package. R Package Version 2.0-10. https://cran.r-project.org/src/contrib/Archive/vegan/. (accessed on 2024-10-02)
[23]	Qiang S, Zhang H (2022) Invasion and management of alien plants in agroecosystems in China. Journal of Nanjing Agricultural University, 45, 957-980. (in Chinese with English abstract)
	[强胜, 张欢 (2022) 中国农业生态系统外来植物入侵及其管理现状. 南京农业大学学报, 45, 957-980.]
[24]	R Core Team (2024) R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna. https://www.r-project.org/. (accessed on 2024-10-02)
[25]	Shen Y, Qiu P, Liao ZY, Wu XG, Sun XM, Zhang L, Pan ZF, Pan KW (2022) Changes in distribution patterns of weed species richness in agricultural lands on Qinghai-Tibet Plateau under climate change. Chinese Journal of Applied and Environmental Biology, 28, 897-908. (in Chinese with English abstract)
	[申源, 邱鹏, 廖梓延, 伍小刚, 孙晓铭, 张林, 潘志芬, 潘开文 (2022) 气候变化下青藏高原农田杂草丰富度格局变化. 应用与环境生物学报, 28, 897-908.]
[26]	Song HJ, Huang S, Jia EH, Dai X, Wignall PB, Dunhill AM (2020) Flat latitudinal diversity gradient caused by the permian-triassic mass extinction. Proceedings of the National Academy of Sciences, USA, 117, 17578-17583.
[27]	Tang QH, Zong DL, Zhou J, Hu XK, Wang T (2024) The potential threat and driving factors of cropland weeds Aegilops tauschii and Ambrosia artemisiifolia under global climate change. Chinese Journal of Ecology, 43, 1130-1140. (in Chinese with English abstract)
	[唐千鸿, 宗冬琳, 周静, 胡小康, 王弢 (2024) 全球气候变化下农田杂草节节麦和豚草的潜在威胁及其驱动因子. 生态学杂志, 43, 1130-1140.]
[28]	Wang JH, Chen W, Zhang YF, Li Y, Shi SJ, Zheng JY, Chen YX (2020) Carbon, nitrogen, and phosphorus stoichiometry and nutrition strategy of invasive species Mikania micrantha with three invasive degrees and native species Siegesbeckia orientalis. Chinese Journal of Ecology, 39, 1994-2003. (in Chinese with English abstract)
	[王桔红, 陈文, 张燕芳, 李云, 史生晶, 郑佳玉, 陈燕霞 (2020) 不同入侵程度的微甘菊及本土种豨莶碳氮磷化学计量特征与营养策略. 生态学杂志, 39, 1994-2003.]
[29]	Wang XG, Wiegand T, Anderson Teixeira KJ, Bourg NA, Hao ZQ, Howe R, Jin GZ, Orwig DA, Spasojevic MJ, Wang SZ, Wolf A, Myers JA (2018) Ecological drivers of spatial community dissimilarity, species replacement and species nestedness across temperate forests. Global Ecology and Biogeography, 27, 581-592.
[30]	Wang YX, Chen Y, Huang LJ, Ma WW, Wang Z, Yu Q, Yan SJ (2020) Research progress of urban weeds in China. Journal of Chinese Urban Forestry, 18(6), 68-72. (in Chinese with English abstract)
	[王云霄, 陈莹, 黄柳菁, 马雯雯, 王喆, 于强, 闫淑君 (2020) 我国城市杂草研究进展. 中国城市林业, 18(6), 68-72.]
[31]	Wang YX, Yan SJ, Ma WW, Pan WY, Chen Y, Zhuang LB (2021) Investigation and analysis of lawn spontaneous plant in Fuzhou National Forest Park. Journal of Chinese Urban Forestry, 19(6), 94-98. (in Chinese with English abstract)
	[王云霄, 闫淑君, 马雯雯, 潘王韵, 陈莹, 庄莉彬 (2021) 福州国家森林公园草坪自生植物调查分析. 中国城市林业, 19(6), 94-98.]
[32]	Wickham H (2016) ggplot2, Elegant Graphics for Data Analysis. Springer-Verlag, New York.
[33]	Wu H, Dong SJ, Su YH, Rao BQ (2023) Recent progress in the responses of invasive plants to climate change. Journal of Xinyang Normal University (Natural Science Edition), 36, 338-344. (in Chinese with English abstract)
	[吴昊, 董思谨, 苏仪函, 饶本强 (2023) 入侵植物对气候变化响应的研究新进展. 信阳师范学院学报(自然科学版), 36, 338-344.]
[34]	Wu XY, Du ZZ, Wang R, Ma ZC, Pan CN, Yan P (2023) Three kinds of Compositae new records in Xinjiang. Journal of Shihezi University (Natural Science), 41, 723-729. (in Chinese with English abstract)
	[吴星月, 杜珍珠, 王睿, 马占仓, 潘成南, 阎平 (2023) 新疆发现3种菊科新记录植物. 石河子大学学报(自然科学版), 41, 723-729.] DOI
[35]	Wu ZY, Sun H, Zhou ZK, Li DZ, Peng H (2011) Floristics of Seed Plants from China. Science Press, Beijing. (in Chinese)
	[吴征镒, 孙航, 周浙昆, 李德铢, 彭华 (2011) 中国种子植物区系地理. 科学出版社, 北京.]
[36]	Wu ZY, Zhou ZK, Li DZ, Peng H, Sun H (2003) The areal-types of the world families of seed plants. Acta Botanica Yunnanica, 25, 245-257. (in Chinese with English abstract)
	[吴征镒, 周浙昆, 李德铢, 彭华, 孙航 (2003) 世界种子植物科的分布区类型系统. 云南植物研究, 25, 245-257.]
[37]	Xing DL, He FL, Buckley L (2019) Environmental filtering explains a U-shape latitudinal pattern in regional β-deviation for eastern north American trees. Ecology Letters, 22, 284-291. DOI PMID
[38]	Yang H, Wang Y, Wang JM, Xia YG, Li JW, Jia XH, Wu B (2021) Effects of environmental filtering and dispersal limitation on the β-diversity of plant communities in the south fringe of Kumtag Desert. Journal of Desert Research, 41(3), 147-154. (in Chinese with English abstract)
	[杨欢, 王寅, 王健铭, 夏延国, 李景文, 贾晓红, 吴波 (2021) 环境过滤和扩散限制对库姆塔格沙漠南缘植物群落β-多样性的影响. 中国沙漠, 41(3), 147-154.] DOI
[39]	Yang WJ, Sun SX, Wang NX, Fan PX, You CC, Wang RQ, Zheng PM, Wang H (2023) Dynamics of the distribution of invasive alien plants (Asteraceae) in China under climate change. Science of the Total Environment, 903, 166260.
[40]	Zeng YX, Jin CZ, Xiang GH, Liu ZF, Shi QH, Peng YL (2017) Distribution and harmfulness of turf weed species in Loudi City. Pratacultural Science, 34, 2272-2278. (in Chinese with English abstract)
	[曾永贤, 金晨钟, 向国红, 刘泽发, 石琪涵, 彭友林 (2017) 娄底市草坪杂草种类、分布及危害. 草业科学, 34, 2272-2278.]
[41]	Zhang ML, Cui YC, Da LJ (2021) Distribution and causes of ruderal communities in different urban habitats of Hangzhou. Journal of East China Normal University (Natural Science), (2), 120-131. (in Chinese with English abstract)
	[张明丽, 崔易翀, 达良俊 (2021) 杭州不同城市生境杂草群落分布格局及其成因. 华东师范大学学报(自然科学版), (2), 120-131.]
[42]	Zhang Y, Song Y, Zhang C, Wang T, Su T, Huang P, Meng H, Li J (2022) Latitudinal diversity gradient in the changing world: Retrospectives and perspectives. Diversity, 14, 334.
[43]	Zhao HX, Ma CY (2002) Investigation on turf weeds in Shenyang area. Journal of Shenyang Normal University (Natural Science), 20, 295-298. (in Chinese with English abstract)
	[赵洪新, 马纯艳 (2002) 沈阳地区常见草坪杂草调查. 沈阳师范学院学报(自然科学版), 20, 295-298.]
[44]	Zheng BH, Chen XY, Ni J (2024) A dataset on the plant growth form and life form of vascular plants in China. Biodiversity Science, 32, 23468. (in Chinese with English abstract) DOI
	[郑博瀚, 陈鑫瑶, 倪健 (2024) 中国维管植物生长型和生活型数据集. 生物多样性, 32, 23468.] DOI

生活型 Life form	种数 No. of species	物种比例 Proportion of species (%)
一年生草本 Annual herbs	96	46.15
一年生或二年生草本 Annual or biennial herbs	2	0.96
二年生草本 Biennial herbs	2	0.96
二年或多年生草本 Biennial or perennial herbs	1	0.48
多年生草本 Perennial herbs	103	49.52
常绿木质藤本 Evergreen woody vines	1	0.48
落叶灌木 Deciduous bush plant	2	0.96
落叶木质藤本 Deciduous woody vines	1	0.48
总计 Total	208	100.00

生活型 Life form	种数 No. of species	物种比例 Proportion of species (%)
一年生草本 Annual herbs	96	46.15
一年生或二年生草本 Annual or biennial herbs	2	0.96
二年生草本 Biennial herbs	2	0.96
二年或多年生草本 Biennial or perennial herbs	1	0.48
多年生草本 Perennial herbs	103	49.52
常绿木质藤本 Evergreen woody vines	1	0.48
落叶灌木 Deciduous bush plant	2	0.96
落叶木质藤本 Deciduous woody vines	1	0.48
总计 Total	208	100.00

科的类型 Types of family	科 Family	属 Genus	占比 Percentage (%)	种 Species	占比 Percentage (%)
≥ 10种 ≥ 10 species (7.5%)	菊科 Asteraceae	30	21.90	46	22.12
≥ 10种 ≥ 10 species (7.5%)	禾本科 Poaceae	29	21.17	40	19.24
	豆科 Fabaceae	9	6.57	15	7.22
5-9种 5-9 species (22.5%)	十字花科 Brassicaceae	6	4.37	8	3.86
5-9种 5-9 species (22.5%)	茜草科 Rubiaceae	5	3.65	7	3.37
	大戟科 Euphorbiaceae	3	2.19	7	3.37
	石竹科 Caryophyllaceae	4	2.92	7	3.37
	莎草科 Cyperaceae	4	2.92	6	2.88
	苋科 Amaranthaceae	2	1.46	6	2.88
	唇形科 Lamiaceae	5	3.65	5	2.4
	堇菜科 Violaceae	1	0.73	5	2.4
	蓼科 Polygonaceae	2	1.46	5	2.4
2-4种 2-4 species (30.0%)	伞形科 Apiaceae	3	2.19	4	1.92
2-4种 2-4 species (30.0%)	蔷薇科 Rosaceae	3	2.19	4	1.92
	玄参科 Scrophulariaceae	2	1.46	4	1.92
	旋花科 Convolvulaceae	3	2.19	4	1.92
	藜科 Chenopodiaceae	2	1.46	4	1.92
	酢浆草科 Oxalidaceae	2	1.46	3	1.45
	车前科 Plantaginaceae	1	0.73	2	0.96
	茄科 Solanaceae	1	0.73	2	0.96
	母草科 Linderniaceae	1	0.73	2	0.96
	牻牛儿苗科 Geraniaceae	1	0.73	2	0.96
	葡萄科 Vitaceae	1	0.73	2	0.96
	鸢尾科 Iridaceae	1	0.73	2	0.96
1种 1 species (40.0%)	凤尾蕨科 Pteridaceae	1	0.73	1	0.48
1种 1 species (40.0%)	海金沙科 Lygodiaceae	1	0.73	1	0.48
	景天科 Crassulaceae	1	0.73	1	0.48
	金星蕨科 Thelypteridaceae	1	0.73	1	0.48
	百合科 Liliaceae	1	0.73	1	0.48
	鳞毛蕨科 Dryopteridaceae	1	0.73	1	0.48
	锦葵科 Malvaceae	1	0.73	1	0.48
	夹竹桃科 Apocynaceae	1	0.73	1	0.48
	毛茛科 Ranunculaceae	1	0.73	1	0.48
	铁角蕨科 Aspleniaceae	1	0.73	1	0.48
	紫草科 Boraginaceae	1	0.73	1	0.48
	忍冬科 Caprifoliaceae	1	0.73	1	0.48
	萝藦科 Asclepiadaceae	1	0.73	1	0.48
	马齿苋科 Portulacaceae	1	0.73	1	0.48
	瓶尔小草科 Ophioglossaceae	1	0.73	1	0.48
	桑科 Moraceae	1	0.73	1	0.48
总计 Total	40	137	100.00	208	100.00

科的类型 Types of family	科 Family	属 Genus	占比 Percentage (%)	种 Species	占比 Percentage (%)
≥ 10种 ≥ 10 species (7.5%)	菊科 Asteraceae	30	21.90	46	22.12
≥ 10种 ≥ 10 species (7.5%)	禾本科 Poaceae	29	21.17	40	19.24
	豆科 Fabaceae	9	6.57	15	7.22
5-9种 5-9 species (22.5%)	十字花科 Brassicaceae	6	4.37	8	3.86
5-9种 5-9 species (22.5%)	茜草科 Rubiaceae	5	3.65	7	3.37
	大戟科 Euphorbiaceae	3	2.19	7	3.37
	石竹科 Caryophyllaceae	4	2.92	7	3.37
	莎草科 Cyperaceae	4	2.92	6	2.88
	苋科 Amaranthaceae	2	1.46	6	2.88
	唇形科 Lamiaceae	5	3.65	5	2.4
	堇菜科 Violaceae	1	0.73	5	2.4
	蓼科 Polygonaceae	2	1.46	5	2.4
2-4种 2-4 species (30.0%)	伞形科 Apiaceae	3	2.19	4	1.92
2-4种 2-4 species (30.0%)	蔷薇科 Rosaceae	3	2.19	4	1.92
	玄参科 Scrophulariaceae	2	1.46	4	1.92
	旋花科 Convolvulaceae	3	2.19	4	1.92
	藜科 Chenopodiaceae	2	1.46	4	1.92
	酢浆草科 Oxalidaceae	2	1.46	3	1.45
	车前科 Plantaginaceae	1	0.73	2	0.96
	茄科 Solanaceae	1	0.73	2	0.96
	母草科 Linderniaceae	1	0.73	2	0.96
	牻牛儿苗科 Geraniaceae	1	0.73	2	0.96
	葡萄科 Vitaceae	1	0.73	2	0.96
	鸢尾科 Iridaceae	1	0.73	2	0.96
1种 1 species (40.0%)	凤尾蕨科 Pteridaceae	1	0.73	1	0.48
1种 1 species (40.0%)	海金沙科 Lygodiaceae	1	0.73	1	0.48
	景天科 Crassulaceae	1	0.73	1	0.48
	金星蕨科 Thelypteridaceae	1	0.73	1	0.48
	百合科 Liliaceae	1	0.73	1	0.48
	鳞毛蕨科 Dryopteridaceae	1	0.73	1	0.48
	锦葵科 Malvaceae	1	0.73	1	0.48
	夹竹桃科 Apocynaceae	1	0.73	1	0.48
	毛茛科 Ranunculaceae	1	0.73	1	0.48
	铁角蕨科 Aspleniaceae	1	0.73	1	0.48
	紫草科 Boraginaceae	1	0.73	1	0.48
	忍冬科 Caprifoliaceae	1	0.73	1	0.48
	萝藦科 Asclepiadaceae	1	0.73	1	0.48
	马齿苋科 Portulacaceae	1	0.73	1	0.48
	瓶尔小草科 Ophioglossaceae	1	0.73	1	0.48
	桑科 Moraceae	1	0.73	1	0.48
总计 Total	40	137	100.00	208	100.00

分级 Classification	属数 No. of genera (%)	种数 No. of species (%)
8-10种 8-10 species	1 (0.73)	9 (4.33)
5-7种 5-7 species	3 (2.19)	15 (7.21)
2-4种 2-4 species	35 (25.55)	86 (41.35)
1种 1 species	98 (71.53)	98 (47.12)
总计 Total	137 (100)	208 (100)