贵阳市主要绿化树种叶面吸滞颗粒物特征及其时空变化

doi:10.11707/j.1001-7488.20200602

摘要/Abstract

摘要：

目的: 分析贵阳市不同树种的单位叶面积颗粒物吸滞量差异及其时空变化，以期为合理选择高效滞尘绿化树种提供依据。方法: 以14个常见园林树种为研究对象，以贵阳市城市广场、城市公园、城郊绿地和城郊森林4个不同污染背景地点为采样点。在每个采样点各个树种分别选择3株样树（除部分树种在某个采样点无分布外），定期在4个样点同步采集叶样。采用基于风蚀原理的气溶胶再悬浮方法，测定单位叶面积的颗粒物吸滞量（M）。采集叶片，电子扫描显微镜拍摄叶面显微结构影像，利用图像分析软件量化分析叶面气孔、表皮毛、叶面粗糙程度、蜡质覆盖程度等形态结构特征因子。利用通径分析方法分析叶面形态结构特征因子对叶面颗粒物吸滞量的影响程度。结果: 所测乔木和灌木2种生活型间的吸滞量无明显差异；树种间的叶面悬浮总颗粒物（TSP）吸滞量（M_TSP）差异显著，各树种M_TSP为1.56~11.14 μg·cm^-2，红花檵木最高，雪松较高，桂花、杜鹃、琴丝竹、女贞和白玉兰居中，香樟、红叶石楠、迎春花、樱花、杨梅、栾树和银杏较弱；通径分析表明，叶面粗糙度、表皮毛密度和长度对叶面TSP吸滞量的影响大于其他叶面微形态因子，具有较多和较长表皮毛且相对粗糙的叶面具有较大吸滞量；叶面吸滞的大颗粒（PM_10~100）和粗颗粒（PM_2.5~10）质量百分比（97.36%）高于背景空气（80.29%），这说明叶面趋向吸滞较大粒径颗粒物（PM_10~100和PM_2.5~10），而对细颗粒（PM_1.0~2.5）和超细颗粒（PM₁）吸滞能力较弱；多数树种冬、春季M值大于夏、秋季；同一树种M值表现为市区采样点高于郊区采样点；同在市区时，树木聚集生长的城市公园采样点高于树木散生的城市广场采样点，呈现出"集聚效应"。结论: 树种间的叶面TSP吸滞量差异显著；影响叶面TSP吸滞量的最主要形态结构因子是叶面粗糙度和表皮毛密度；叶面对大颗粒和粗颗粒的吸滞量高于细颗粒和超细颗粒，高污染地点的单位叶面积吸滞量大于低污染地点。以树木叶面形态结构因子为评价指标，可筛选滞尘能力强的树种。14种参试树种中红花檵木、雪松和桂花的叶面颗粒物吸滞量远大于其余树种，可用于缓解大气颗粒物污染。

关键词: 城市绿化树种, 颗粒物吸滞量, 叶面微形态结构

Abstract:

Objective: The aim of this study is to quantify the particulate matters (PM) retained per unit leaf area by different tree species and its spatio-temporal variation in Guiyang City, in order to provide a scientific basis for the rational selection of landscaping tree species with higher capacity of retaining PMs. Method: Fourteen commonly used landscaping tree species growing at 4 sites, urban square, urban park, suburban green area, and suburban forest, in Guiyang City each with different levels of pollution. Leaf samples were collected regularly from 3 trees of each species (some species are not present at certain sites) at the same time. The aerosol re-suspension method based on the wind erosion principle was applied to measure the retained PM quantity per unit leaf area (M). The micro-morphological and structural characteristics (stomata density, stoma size, stomata opening size, roughness, vein density, groove width, wax coverage index, epidermal hair length, epidermal hair density, etc.) of leaves were quantitatively analyzed using image analysis software. The influence of leaf morphology and structure characteristics on the leaf retained PM was analyzed by means of path analysis. Result: It showed that the site means of M_TSP of all studied tree species varied within a range of 1.56-11.14 μg·cm^-2, with non-significant difference between trees and shrubs, but a significant difference among tree species. The tree species of Loropetalum chinense var. rubrum showed the highest quantity of PM retention, followed by Cedrus deodara, Osmanthus fragrans, Rhododendron simsii, Bambusa multiplex, Ligustrum lucidum, and Magnolia denudata, while other tree species showed a weak capacity of PM retention. Among the structural morphological characteristics, the leaf surface roughness, the epidermal hair density, and epidermal hair length were the major factors affecting PM retention compared to other ones. Therefore, the leaves with higher epidermal hair density, bigger epidermal hair length, and rougher leaf surface presented a higher PM retention. The weight ratios of different PMs retained by leaves were not the same as that in the ambient air. The weight ratio of retained coarse and large PMs was 97.36%, while it was 80.29% in the ambient air, indicating that leaves tend to retain more PMs with bigger diameters (such as PM_2.5-100) but less fine PMs (such as PM_1-2.5 and PM₁). Most tree species showed a higher PM retention in winter and spring than in summer and autumn. For the same tree species, the PM retention in urban sites was higher than that in suburban sites. Among the 2 urban sites with a high air PM density, the PM retention quantity was higher in urban park than in urban square, probably due to the more concentrated distribution of trees in the urban parks which leads to a more favorable microclimate to capture more PM on leaf surface, i.e., an agglomeration effect. Conclusion: A significant difference in the PM retaining capacity exists among tree species. The main factors affecting the leaf PM retaining capacity are the leaf surface roughness and the epidermal hair density. The leaves tend to retain more large and coarse PM but less fine and ultra fine PM. The quantity of retained PM by leaves at more polluted sites is higher than that at less polluted sites. The micro-morphological and structural characteristics of leaves can be used as evaluation indicators for selecting tree species with high PM retention capacity. L. chinense var. rubrum, C. deodara, and O. fragrans can be used in urban greening for mitigating the PM pollution because of their high PM retention capacity.

Key words: urban landscaping tree species, quantity of PM retention, micro structure of leaf morphology

中图分类号:

S371.8

刘延惠,侯贻菊,舒德远,杨冰,崔迎春,丁访军. 贵阳市主要绿化树种叶面吸滞颗粒物特征及其时空变化[J]. 林业科学, 2020, 56(6): 12-25.

Yanhui Liu,Yiju Hou,Deyuan Shu,Bing Yang,Yingchun Cui,Fangjun Ding. Properties and Spatio-Temporal Variation of Leaf Retained Particulate Matters of the Main Tree Species Planted in Guiyang City[J]. Scientia Silvae Sinicae, 2020, 56(6): 12-25.

图/表 14

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表5

表6

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图6

表7

叶面微形态结构特征参数"

树种 Tree species	气孔密度 Density of stoma/ mm^-2	气孔开口面积 Area of stoma opening/ (mm²·mm^-2)	气孔开度 Opening degree of stoma	气孔器纵径 Length of stomatal apparatus/ μm	气孔器横径 Width of stomatal apparatus/ μm	气孔器横纵径比 Ratio of width to length of stomatal apparatus	气孔口纵径 Length of stomatal opening/ μm	气孔口横径 Width of stomatal opening/ μm	气孔口横纵径比 Ratio of width to length of stomatal opening	粗糙度 Roughness	叶脉密度 Vein density/ (μm·cm^-2)	蜡质覆盖指数 Wax coverage index	沟槽宽度 Width of groove/ μm	疣状突起密度 Protrusions density/ mm^-2	表皮毛密度 Epidermis hair density/ mm^-2	表皮毛长 Length of epidermis hair/ μm
桂花O. fragrans	596.02	0.026	0.07	28	23.67	0.85	9.16	5.96	0.65	0.45	1 183.47	0.75	0	9.56	0	0
樱花C.subhirtella	360.91	0.054	0.21	36.16	17.71	0.49	17.82	4.95	0.28	0.38	2 925.00	0.75	14.4	0	0	0
香樟C.camphora	199.71	0.010	0.09	32.31	24.80	0.77	17.16	5.79	0.34	0.36	908.57	0.50	0	0	5.96	227.35
银杏G.biloba	62.23	0.027	0.21	52.15	46.99	0.9	23.26	19.65	0.84	0.2	753.88	0.25	9.05	0	0	0
迎春花J.nudiflorum	137.71	0.009	0.25	23.98	19.37	0.81	14.78	6.73	0.46	0.57	551.33	0.75	5.82	0	0	0
琴丝竹B.miltiplex	398.19	0.023	0.19	21.13	19.74	0.93	8.61	6.26	0.73	0.49	3 600.31	0.75	3.7	0	53.32	113.65
女贞L. lucidum	230.61	0.036	0.33	28.16	25.69	0.91	17.68	9.45	0.53	0.43	217.25	0.25	5.21	5.10	0	0
红花檵木L. chinense var. rubrum	332.32	0.027	0.15	23.38	28.76	1.23	9.69	4.94	0.51	0.44	1 816.56	0.50	10.1	0	64.03	251.90
红叶石楠P. fraseri	197.42	0.025	0.17	32.93	29.40	0.89	16.61	9.33	0.56	0.05	0	0.75	0	5.90	0	0
白玉兰M. denudata	289.52	0.023	0.10	31.86	45.31	1.42	18.92	5.24	0.28	0.34	724.69	0.25	25.35	0	28.01	24.70
杜鹃R.simsii	446.72	0.038	0.19	23.38	26.26	1.12	11.43	5.20	0.45	0.63	0	0.50	6.62	0	12.04	428.65
雪松C.deodara	34.24	0.022	0.23	67.73	46.50	0.69	37.26	21.19	0.57	0.57	2 456.70	0.50	6.23	0	0	0
杨梅M.rubra	424.30	0.024	0.12	22.25	21.71	0.98	8.36	5.63	0.67	0.38	1 361.39	0.75	9.23	1.63	0	0
栾树K.paniculata	333.21	0.005	0.12	14.23	8.46	0.59	7.80	1.78	0.23	0.14	2 649.98	0.5	4.6	0	11.02	57.43

表7

表8

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树种Tree species	样树特征Characteristics of sample trees				采样点Sample sites
树种Tree species	DBH/cm	冠幅 Canopy diameter/m	冠幅投影面积 Canopy projected area/m²	LAI	US	UP	SG	SF
桂花O. fragrans	11.85	4.26	16.92	2.53	+	+	+	+
樱花C. subhirtella	23.7	5.50	23.75	2.47	+	+	+	+
香樟C. camphora	35.87	8.78	65.77	2.50	+	+	+	+
银杏G. biloba	21.00	3.80	11.34	2.46	+	+	+	-
迎春花J. nudiflorum	1.80	5.20	18.78	2.47	+	+	+	-
琴丝竹B. miltiplex	2.17	0.70	0.80	3.32	+	+	+	+
女贞L. lucidum	9.20	3.90	11.94	2.48	-	+	+	+
红花檵木L.chinense var. rubrum	3.74	1.76	2.51	2.78	+	+	+	+
红叶石楠P. fraseri	6.45	2.22	4.04	4.24	+	+	+	-
白玉兰M. denudata	17.95	4.70	17.00	2.78	-	+	+	+
杜鹃R. simsii	2.65	1.29	1.28	2.62	+	+	+	-
雪松C. deodara	52.30	10.33	87.42	3.18	+	+	+	+
杨梅M. rubra	24.10	4.95	32.43	2.58	+	-	-	+
栾树K. paniculata	21.93	5.40	23.18	2.89	-	-	-	+

指标Index	符号Sign	单位Unit	定义Definition
气孔密度Density of stoma	D_s	mm^-2	单位叶表面积的气孔数量Number of stoma per unit leaf area
气孔开口面积Area of stoma opening	S_so	mm²·mm^-2	单位叶面积的气孔开口面积Area of stoma opening per unit leaf area
气孔开度Opening degree of stoma	O_s	μm²·μm^-2	单个气孔开口面积与气孔面积比Ratio of stomatal opening area and stoma area
气孔器纵径Length of stomatal apparatus	L_s	μm
气孔器横径Width of stomatal apparatus	W_s	μm
气孔器横纵径比Ratio of width to length of stomatal apparatus	R_s
气孔口纵径Length of stomatal opening	L_so	μm
气孔口横径Width of stomatal opening	W_so	μm
气孔口横纵径比Ratio of width to length of stomatal opening	R_so
粗糙度Roughness	RD	无量纲 Dimensionless	单位叶表面积斑块数量的相对值Relative value of the number of plaques per unit leaf surface area
叶脉密度Vein density	D_v	μm·mm^-2	单位叶表面的叶脉长度Length of vein per unit leaf surface area
沟槽宽度Width of groove	W_g	μm	叶表面蜡质或角质突起间的下凹沟槽宽度Width of lower concave groove between waxy or cuticular processes on leaf surface
蜡质覆盖指数Wax coverage index	I_w	无量纲 Dimensionless	叶表面蜡质/角质覆盖程度Degree of waxy or cutin covering on leaf surface
疣状突起密度Protrusions density	D_p	mm^-2	单位叶表面积的乳状、瘤状突起数量Number of nipples or protrusions per unit leaf surface area
表皮毛长length of epidermis hair	L_h	μm	叶表面表皮毛的长度Length of epidermis hair
表皮毛密度Epiderm hair density	D_h	mm^-2	单位叶表面积的表皮毛数量Number of epiderm is hair per unit leaf surface area

项目Item	US	UP	SG	SF
高峰交通量Peak traffic volume /h^-1	4 745	2 160	1 830	—
换算系数k Conversion coefficient k	2.2	1.0	0.85	0.6

采样点 Sampling sites	差异来源 Variance sources	平方和 Sum of squares	df	均方 Mean square	F	显著性 Significance
	组间Between groups	30.248	1	30.248	1.573	0.212
1	组内Within the group	2 172.309	113	19.224
	总和Total	2 202.558	114

	组间Between groups	6.393	1	6.393	0.14	0.709
2	组内Within the group	7 723.889	169	45.703
	总和Total	7 730.282	170

	组间Between groups	0.070	1	0.070	0.007	0.932
3	组内Within the group	1 091.703	115	9.493
	总和Total	1 091.772	116

	组间Between groups	18.273	1	18.273	2.918	0.092
4	组内Within the group	457.060	73	6.261
	总和Total	475.333	74

类别 Classification	种数 Species	M′
类别 Classification	种数 Species	TSP	PM₁₀	PM_2.5	PM₁
Ⅰ	2	10.255 ±1.255	4.753 ±0.926	0.250 ±0.034	0.021 ±0.005
Ⅱ	1	6.235	2.605	0.169	0.021
Ⅲ	11	2.635 ±0.742	1.126 ±0.338	0.068 ±0.023	0.006 ±0.002
加权均值Weighted mean	14	3.981 ±2.919	1.750 ±1.388	0.102 ±0.072	0.009 ±0.007