吉林蛟河42 hm2针阔混交林样地植物种-面积关系

doi:10.3724/SP.J.1258.2012.00030

摘要/Abstract

摘要：

种-面积关系是生态学中的基本问题, 其构建方式对种-面积关系的影响以及最优种-面积模型的选择仍然存在争议。该文利用吉林蛟河42 hm²针阔混交林样地数据, 分别采用巢式样方法和随机样方法建立对数模型、幂函数模型和逻辑斯蒂克模型, 并通过赤池信息量准则(AIC)检验种-面积模型优度。结果表明, 种-面积关系受到取样方法的影响, 随机样方法的拟合效果优于巢式样方法。采用随机样方法构建的幂指数模型(AIC = 89.11)和逻辑斯蒂克模型(AIC = 71.21)优于对数模型(AIC = 113.81)。根据AIC值可知, 随机样方法构建的逻辑斯蒂克模型是拟合42 hm²针阔混交林样地种-面积关系的最优模型。该研究表明: 在分析种-面积关系时不仅应考虑尺度效应, 还需注意生境变化及群落演替的影响。

关键词: 拟合优度, 巢式样方, 随机样方, 种-面积关系

Abstract:

Aims The Species Area Relationship (SAR) is a fundamental pattern in ecology. Recent analyses have often demonstrated substantial uncertainty in selecting the best SAR model for a data set. Our objective was to understand the effects of sample design on species-area relations, in order to suggest a more appropriate SAR model for the given plot data.
Methods A long-term 42 hm²forest plot was established in conifer and board-leaved mixed forest in Jiaohe, China. All trees with diameter at breast height (DBH) > 1 cm were tagged and their height, DBH and crown diameter recorded. We propose three SARs models (logarithmic function, power function and logistic function) to compare SARs constructed from nested design and random design. We use Akaike Information Criterion (AIC) to compare the quality fit of each SAR model given the data.
Important findings The way of constructing SARs influences the outcome. The random design showed significantly better goodness of fit of SARs model than the nested design. Among the three SAR models, Logistic function model from the random design was the best, suggesting it provided a reasonable description of the species-area relationship in the plot. This study demonstrates the signiﬁcance of scale variance in species-area relationships; the effects of area on species richness are variable and can be scale dependent. However, because the species distribution patterns and spatial scale vary greatly, further work is needed to consider environmental effects and the community succession on different spatial scales.

Key words: goodness of fit, nest sample design, random sample design, species-area relationship

姜俊, 张春雨, 赵秀海. 吉林蛟河42 hm²针阔混交林样地植物种-面积关系. 植物生态学报, 2012, 36(1): 30-38. DOI: 10.3724/SP.J.1258.2012.00030

JIANG Jun, ZHANG Chun-Yu, ZHAO Xiu-Hai. Plant species-area relationship in a 42-hm² research plot of coniferous and board-leaved mixed forest in Jiaohe, Jilin Province, China. Chinese Journal of Plant Ecology, 2012, 36(1): 30-38. DOI: 10.3724/SP.J.1258.2012.00030

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.plant-ecology.com/CN/10.3724/SP.J.1258.2012.00030

https://www.plant-ecology.com/CN/Y2012/V36/I1/30

图/表 7

参考文献 35

[1]	Anderson DR, Burnham KP (1994). AIC model selection in over dispersed capture-recapture data. Ecology, 75,1780-1793.
[2]	Archibald EEA (1949). The specific character of plant communities. II. A quantitative approach. Journal of Ecology, 37,274-288.
[3]	Arrhenius O (1921). Species and area. Journal of Ecology, 9,95-99.
[4]	Bartha S, Ittzés P (2001). Local richness-species pool ratio: a consequence of the species-area relationship. Folia Geobotanica, 36,9-23.
[5]	Carey S, Harte J, del Moral R (2006). Effect of community assembly and primary succession on the species-area relationship in disturbed ecosystems. Ecography, 29,866-872.
[6]	Coleman DB (1981). On random placement and species-area relations. Mathematical Biosciences, 54,191-215.
[7]	Connor EF, McCoy ED (1979). The statistics and biology of the species-area relationship. The American Naturalist, 113,791-833.
[8]	Fattorini S (2007). To fit or not to fit? A poorly fitting procedure produces inconsistent results when the species-area relationship is used to locate hotspots. Biodiversity and Conservation, 16,2531-2538.
[9]	Fisher RA, Corbet AS, Williams CB (1943). The relation between the number of species and the number of individuals in a random sample of an animal population. Journal of Animal Ecology, 12,42-58.
[10]	Fridley JD, Peet RK, Wentworth TR, White PS (2005). Connecting fine and broad scale species-area relationships of southeastern U.S. flora. Ecology, 86,1172-1177.
[11]	Gleason HA (1922). On the relation between species and area. Ecology, 3,158-162.
[12]	Gleason HA (1925). Species and area. Ecology, 6,66-74.
[13]	Hao ZQ (郝占庆), Li BH (李步杭), Zhang J (张健), Wang XG (王绪高), Ye J (叶吉), Yao XL (姚晓琳) (2008). Broad-leaved Korean pine ( Pinus koraiensis) mixed forest plot in Changbaishan (CBS) of China: community composition and structure. Journal of Plant Ecology (Chinese Version)(植物生态学报), 32,238-250. (in Chinese with English abstract)
[14]	Harte J, Smith AB, Storch D (2009). Biodiversity scales from plots to biomes with a universal species-area curve. Ecology Letters, 12,789-797. DOI URL PMID
[15]	He FL, Legendre P (1996). On species-area relations. The American Naturalist, 148,719-737.
[16]	He FL, Legendre P (2002). Species diversity patterns derived from species-area models. Ecology, 83,1185-1198.
[17]	He FL (何芳良), Hu XS (胡新生) (2007). Neutral theory and diversity patterns. In: Wu JG (邬建国), Ge JP (葛剑平), Han XG (韩兴国), Yu ZL (于振良), Zhang DY (张大勇) eds. Lectures in Modern Ecology (Ⅲ): Advances and Key Topics (现代生态学讲座Ⅲ: 学科进展与热点论题). Higher Education Press, Beijing. 30. (in Chinese)
[18]	Hoylet M (2004). Causes of the species-area relationship by trophic level in a field-based microecosystem. Proceedings of the Royal Society B: Biological Series, 271,1159-1164.
[19]	Inouye RS (1998). Species-area curves and estimates of total species richness in an old-field chronosequence. Plant Ecology, 137,31-40.
[20]	Kilburn PD (1963). Exponential values for the species-area relation. Science, 141,1276. URL PMID
[21]	Lomolino MV (2001). The species-area relationship: new challenges for an old pattern. Progress in Physical Geography, 25,1-21.
[22]	MacArthur RH, Wilson EO (1967). Island Biogeography. Princeton University Press, Princeton.
[23]	Malcolm JR, Liu CR, Neilson RP, Hansen L, Hannah L (2006). Global warming and extinctions of endemic species from biodiversity hotspots. Conservation Biology, 20,538-548. DOI URL PMID
[24]	Palmer MW, White PS (1994). Scale dependence and the species-area relationship. The American Naturalist, 144,717-740.
[25]	Pastor J, Downing A, Erickson HE (1996). Species-area curves and diversity-productivity relationships in beaver meadows of Voyageurs National Park, Minnesota, USA. Oikos, 77,399-406.
[26]	Pimm SL, Raven P (2000). Extinction in number. Nature, 403,843-845. DOI URL PMID
[27]	Scheiner SM (2003). Six types of species-area curves. Global Ecology and Biogeography, 12,441-447.
[28]	Scheiner SM (2007). Evaluation of species-area functions using Sonoran Desert plant data: not all species-area curves are power functions. Oikos, 116,1930-1940.
[29]	Tjorve E (2003). Shapes and functions of species-area curves: a review of possible models. Journal of Biogeography, 30,827-835.
[30]	Tjorve E, Kunin WE, Polce C, Tjorve KMC (2008). Species-area relationship: separating the effects of species abundance and spatial distribution. Journal of Ecology, 96,1141-1151.
[31]	Ugland KI, Gray JS, Ellingsen KE (2003). The species- accumulation curve and estimation of species richness. Journal of Animal Ecology, 72,888-897.
[32]	Ulrich W, Buszko J (2007). Sampling design and the shape of species-area curves on the regional scale. Acta Oecolo- gica, 31,54-59.
[33]	Weiher E (1999). The combined effects of scale and productivity on species richness. Journal of Ecology, 87,1005-1011.
[34]	Wu ZY (吴征镒), Zhou ZK (周浙昆), Li DZ (李德铢), Peng H (彭华), Sun H (孙航) (2003). The areal-types of the world families of seed plants. Acta Botanica Yunnanica (云南植物研究), 25,245-257. (in Chinese with English abstract)
[35]	Zhang CY (张春雨), Zhao XH (赵秀海), Zhao YZ (赵亚洲) (2009). Community structure in different successional stages in north temperate forests of Changbai Mountains, China. Chinese Journal of Plant Ecology (植物生态学报), 33,1090-1100. (in Chinese with English abstract)

分布区类型 Distribution area type	属数 No. of genera	比率 Rate (%)
1 世界分布 Cosmopolitan distribution	1	3. 57
2 泛热带分布 Pantropic distribution	1	3. 57
8 北温带分布 North temperate distribution	20	71. 40
10 旧世界温带分布 Old world temperate distribution	1	3. 57
14 东亚分布 East Asia distribution	4	14. 29
14-2 中国-日本分布 Sino-Japan distribution	1	3. 57
合计 Total	28	100. 00

分布区类型 Distribution area type	属数 No. of genera	比率 Rate (%)
1 世界分布 Cosmopolitan distribution	1	3. 57
2 泛热带分布 Pantropic distribution	1	3. 57
8 北温带分布 North temperate distribution	20	71. 40
10 旧世界温带分布 Old world temperate distribution	1	3. 57
14 东亚分布 East Asia distribution	4	14. 29
14-2 中国-日本分布 Sino-Japan distribution	1	3. 57
合计 Total	28	100. 00

树种 Tree species	多度 Abundance	胸高断面积 Basal area (m²?hm^-2)	占总胸高断面积的比率 Percentage of total basal area (%)	每公顷株数 Individuals per hectare	最大胸径 Maximum DBH (cm)
紫椴 Tilia amurensis	2 765	3. 29	10. 31	66	82.3
胡桃楸 Juglans mandshurica	2 113	3. 65	11. 43	50	82.6
色木槭 Acer mono	9 604	5. 21	16. 32	229	90.0
红松 Pinus koraiensis	2 546	4. 28	13. 41	60	81.3
水曲柳 Fraxinus mandshurica	2 155	3. 62	11. 34	51	86.6
其他 Other	35 469	11. 86	37. 17	844	108.1
总计 Total	54 652	31. 91	100	1 301

树种 Tree species	多度 Abundance	胸高断面积 Basal area (m²?hm^-2)	占总胸高断面积的比率 Percentage of total basal area (%)	每公顷株数 Individuals per hectare	最大胸径 Maximum DBH (cm)
紫椴 Tilia amurensis	2 765	3. 29	10. 31	66	82.3
胡桃楸 Juglans mandshurica	2 113	3. 65	11. 43	50	82.6
色木槭 Acer mono	9 604	5. 21	16. 32	229	90.0
红松 Pinus koraiensis	2 546	4. 28	13. 41	60	81.3
水曲柳 Fraxinus mandshurica	2 155	3. 62	11. 34	51	86.6
其他 Other	35 469	11. 86	37. 17	844	108.1
总计 Total	54 652	31. 91	100	1 301

取样方法 Sampling design	种-面积模型 Species-area model	模型参数 Model parameter
取样方法 Sampling design	种-面积模型 Species-area model	B	Z	A	AIC
巢式取样 Nest sample design	对数模型 Logarithmic	-22. 16^**	5. 46^***	-	129. 97
	幂函数模型 Power	3. 11^***	0. 22^***	-	95. 91
	逻辑斯蒂克模型 Logistic	1. 75^***	0. 32^***	0. 02^***	84. 67
随机取样 Random sample design	对数模型 Logarithmic	-20. 43^***	5. 52^***	-	89. 11
	幂函数模型 Power	4. 56^***	0. 19^***	-	113. 81
	逻辑斯蒂克模型 Logistic	1. 45^***	0. 39^***	0. 02^***	71. 21

吉林蛟河42 hm²针阔混交林样地植物种-面积关系

Plant species-area relationship in a 42-hm² research plot of coniferous and board-leaved mixed forest in Jiaohe, Jilin Province, China

全文

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 7

参考文献 35

相关文章 2

编辑推荐

Metrics

本文评价

取样方法 Sampling design	种-面积模型 Species-area model	AIC
取样方法 Sampling design	种-面积模型 Species-area model	10 hm²	25 hm²	42 hm²
巢式取样 Nest sample design	对数模型 Logarithmic	129. 91	150. 61	129. 97
	幂函数模型 Power	81. 11	97. 61	95. 91
	逻辑斯蒂克模型 Logistic	82. 63	94. 06	84. 67
随机取样 Random sample design	对数模型 Logarithmic	75. 31	126. 98	89. 11
	幂函数模型 Power	62. 57	94. 42	113. 81
	逻辑斯蒂克模型 Logistic	94. 81	97. 42	71. 21

[1]	曹珍, 刘永英, 宋世凯, 张莉娜, 高德. 陆地生境岛屿藓类植物小岛屿效应驱动因素分析——以太行山脉中段山顶为例[J]. 植物生态学报, 2023, 47(1): 65-76.
[2]	池秀莲, 唐志尧. 面积、温度及分布区限制对物种丰富度海拔格局的影响: 以秦岭太白山为例[J]. 植物生态学报, 2011, 35(4): 362-370.