祁连山东大河林区煤矿修复对地表甲虫多样性的影响

doi:10.7522/j.issn.1000-694X.2023.00031

摘要/Abstract

摘要：

覆土和恢复草本植物可以快速改善高寒山区煤矿矿区环境，植被和土壤环境变化会强烈影响地表甲虫的分布及多样性，煤矿矿区海拔影响甲虫的群落结构变化。以地处祁连山中部的东大河林区为研究区，依据海拔选择宏达、头沟大坂和下泉沟3个典型煤矿作为研究对象，解析高寒山区煤矿人工修复对地表甲虫多样性的影响规律，确定影响地表甲虫分布的主要环境要素。结果表明：东大河林区人工覆土和恢复草本植被的煤矿矿区5年后，煤矿修复区和对照区地表甲虫群落组成还存在一定差异，海拔较高的下泉沟煤矿修复区和对照区地表甲虫群落的平均相异性（84.4%）高于海拔较低的宏达（54.6%）和头沟大坂（57.2%）煤矿。煤矿修复显著提高了头沟大坂和下泉沟煤矿地表甲虫的活动密度，地表甲虫的物种丰富度仅在下泉沟煤矿修复区显著高于对照区。煤矿修复对大、中型甲虫影响较小，但提高了小型甲虫的活动密度和物种丰富度，这在下泉沟煤矿表现尤为明显。海拔、坡度、草本盖度和土壤有机碳含量是影响煤矿修复区和对照区地表甲虫分布的主要环境因子，它们解释了地表甲虫群落变异的22.1%。大、中型地表甲虫分布与海拔和坡度密切相关，而小型地表甲虫分布与草本盖度变化有关。祁连山区煤矿修复改变了植被和土壤环境，提高了小型甲虫的活动密度和物种丰富度，而大、中型甲虫的分布则主要受海拔及坡度变化的影响，它们对煤矿修复及海拔变化的响应模式不同决定了地表甲虫多样性变化。

关键词: 祁连山, 东大河林区, 煤矿修复, 地表甲虫多样性, 个体大小

Abstract:

Mulching with guest soil and rapid vegetation restoration in the coal mining area of the alpine mountain will greatly affect the distribution and diversity of ground beetles， and the change of altitude in coal mining areas will affect the community structure of ground beetles. In this paper， Dongdahe forest area in the middle of Qilian Mountains was selected as a research area， and three typical coal mines， Hongda （HD）， Tougoudaban （TGDB） and Xiaquangou （XQG） were selected as research objects according to the altitude gradient. In the three mine remediation areas and the control area （adjacent grassland）， we systematically investigated species composition and quantitative changes in ground beetles using traps and environmental factor. The impact of artificial coal mine restoration on the diversity of carabid beetles in the Qilian Mountains was analyzed and the response pattern of carabid beetle diversity to coal mine restoration was determined. Moreover， the main environmental factors affecting the distribution of ground beetles were determined by canonical correspondence analysis and correlation analysis. The main results are as follows. After five years of reclamation in the Dongdahe forest area， the composition of the ground beetle population differed a little between the coal mine restoration and control areas and varied with the elevation gradient. Furthermore， the average dissimilarity （84.4%） of the ground beetle communities at the coal mine restoration area and in the control area was higher in higher-elevation XQG coal mines than in lower-elevation HD and TGDB coal mines （54.6% and 57.2%， respectively）. The activity density of ground beetles at the restoration area of TGDB and XQG coal mines was significantly higher than that in the control area， and the species richness of ground beetles at the restoration area of XQG coal mines was significantly higher than that at the control areas. The functional traits of ground beetles， such as body size， influenced the response patterns of different beetle species to coal mine restoration. The coal mine restoration significantly increased the activity density and species richness of small beetles in the three coal mines， most notably in the XQG coal mine， and had little impact on large and medium-sized beetles. The result of the CCA shows that elevation gradient， slope degree， herbaceous cover and soil organic carbon content were key factors affecting ground beetle aggregation in the restoration area and the control area of the three coal mines， explaining 22.1% of the variation in ground beetle communities. Furthermore， through correlation analysis， we found that the distribution of large and medium-sized ground beetles was closely related to altitude gradient and slope degree， while the distribution of small ground beetles is related to change in herbaceous cover. In conclusion， the vegetation and soil environment changed by coal mine restoration in Qilian Mountains increased the activity density and species richness of small beetles， while the distribution of large and medium-sized beetles was mainly affected by altitude gradient and slope degree， and determined change in the response of ground beetle diversity to the restoration of the coal mine in the Qilian Mountains.

Key words: Qilian Mountains, Dongdahe forest area, coal mine restoration, ground beetle diversity, body size

中图分类号:

S154.5

孙小霞, 冯怡琳, 王永珍, 罗维成, 杨竟艺, 史宏亮, 刘继亮. 祁连山东大河林区煤矿修复对地表甲虫多样性的影响[J]. 中国沙漠, 2023, 43(6): 176-186.

Xiaoxia Sun, Yilin Feng, Yongzhen Wang, Weicheng Luo, Jingyi Yang, Hongliang Shi, Jiliang Liu. Response of ground beetle diversity to coal mine restoration in Dongdahe forest area of the Qilian Mountains[J]. Journal of Desert Research, 2023, 43(6): 176-186.

图/表 6

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地表甲虫	宏达		头沟大坂		下泉沟
地表甲虫	修复区	对照区	修复区	对照区	修复区	对照区
云纹虎甲 (Cicindela elisae)	0	0	1	0	0	0
暗步甲种1 (Amara sp. 1)	2	1	23	22	23	3
锥须步甲种1 (Bembidion sp.1)	15	1	121	18	47	3
锥须步甲种2 (Bembidion sp.2)	4	0	2	2	5	0
锥须步甲种3 (Bembidion sp.3)	0	0	2	0	0	0
肉步甲 (Broscus sp.)	1	1	0	0	0	0
碎纹步甲 (Carabus modestulus)	0	0	1	7	7	0
纹鞘步甲 (Carabus sculptipennis)	26	25	10	6	5	0
双斑猛步甲 (Cymindis binotata)	0	1	0	0	0	0
婪步甲 (Harpalus sp.)	1	3	0	0	0	0
盗甲 (Leistus farkaci)	3	1	11	4	4	1
伪葬步甲 (Pseudotaphoxenus originalis)	2	0	0	0	0	0
伪葬步甲 (Pseudotaphoxenus sp.)	0	0	5	2	0	0
通缘步甲 (Pterostichus haptoderoides)	0	5	0	0	0	0
距步甲 (Zabrusprzewalskii)	0	0	1	0	0	0
隐翅虫科 (Staphylinidae spp.)	28	9	19	32	22	0
一角甲 (Notoxus monoceros)	1	0	0	0	0	0
大红斑葬甲 (Necrophorus japonicus)	5	5	1	0	0	0
葬甲 (Necrophorus sp.)	1	0	0	0	1	0
密条草天牛 (Eodorcadion virgatum)	0	0	0	1	0	0
梨象属1种 (Apion sp.)	0	2	2	0	0	0
船象属1种 (Baris sp.)	0	0	4	0	0	0
叶象 (Donus nidensis)	3	6	0	0	0	0
绿叶象 (Phyllobius sp.)	0	0	1	1	1	0
黄褐纤毛象 (Tanymecus urbanus)	0	0	0	1	0	0
蜉金龟种1 (Aphodius sp.1)	0	5	0	1	0	0
蜉金龟种2 (Aphodius sp.2)	0	6	0	0	0	0
墨侧裸蜣螂 (Gymnopleurus mopsus)	0	0	0	0	1	1
东鳖甲1种 (Anatolica sp.)	0	1	0	0	0	0
贞琵甲1种 (Agnaptoria sp.)	0	0	4	5	0	0
丸甲科1种 (Byrrhidae sp.)	1	0	0	0	0	0
阎甲科1种 (Histeridae sp.)	0	1	0	0	0	0
长泥甲科1种 (Neoheterocerus sp.)	1	0	0	0	0	0

地表甲虫	宏达		头沟大坂		下泉沟
地表甲虫	修复区	对照区	修复区	对照区	修复区	对照区
云纹虎甲 (Cicindela elisae)	0	0	1	0	0	0
暗步甲种1 (Amara sp. 1)	2	1	23	22	23	3
锥须步甲种1 (Bembidion sp.1)	15	1	121	18	47	3
锥须步甲种2 (Bembidion sp.2)	4	0	2	2	5	0
锥须步甲种3 (Bembidion sp.3)	0	0	2	0	0	0
肉步甲 (Broscus sp.)	1	1	0	0	0	0
碎纹步甲 (Carabus modestulus)	0	0	1	7	7	0
纹鞘步甲 (Carabus sculptipennis)	26	25	10	6	5	0
双斑猛步甲 (Cymindis binotata)	0	1	0	0	0	0
婪步甲 (Harpalus sp.)	1	3	0	0	0	0
盗甲 (Leistus farkaci)	3	1	11	4	4	1
伪葬步甲 (Pseudotaphoxenus originalis)	2	0	0	0	0	0
伪葬步甲 (Pseudotaphoxenus sp.)	0	0	5	2	0	0
通缘步甲 (Pterostichus haptoderoides)	0	5	0	0	0	0
距步甲 (Zabrusprzewalskii)	0	0	1	0	0	0
隐翅虫科 (Staphylinidae spp.)	28	9	19	32	22	0
一角甲 (Notoxus monoceros)	1	0	0	0	0	0
大红斑葬甲 (Necrophorus japonicus)	5	5	1	0	0	0
葬甲 (Necrophorus sp.)	1	0	0	0	1	0
密条草天牛 (Eodorcadion virgatum)	0	0	0	1	0	0
梨象属1种 (Apion sp.)	0	2	2	0	0	0
船象属1种 (Baris sp.)	0	0	4	0	0	0
叶象 (Donus nidensis)	3	6	0	0	0	0
绿叶象 (Phyllobius sp.)	0	0	1	1	1	0
黄褐纤毛象 (Tanymecus urbanus)	0	0	0	1	0	0
蜉金龟种1 (Aphodius sp.1)	0	5	0	1	0	0
蜉金龟种2 (Aphodius sp.2)	0	6	0	0	0	0
墨侧裸蜣螂 (Gymnopleurus mopsus)	0	0	0	0	1	1
东鳖甲1种 (Anatolica sp.)	0	1	0	0	0	0
贞琵甲1种 (Agnaptoria sp.)	0	0	4	5	0	0
丸甲科1种 (Byrrhidae sp.)	1	0	0	0	0	0
阎甲科1种 (Histeridae sp.)	0	1	0	0	0	0
长泥甲科1种 (Neoheterocerus sp.)	1	0	0	0	0	0

指标		对照（CM）		生态修复（ER）		CM × ER
指标		F_2,18	P	F_1,18	P	F_2,18	P
群落结构	活动密度	16.88	<0.001	30.63	<0.001	6.93	0.010
	物种丰富度	29.46	<0.001	15.36	0.002	4.73	0.031
	多样性指数	6.14	0.015	0.14	0.712	4.43	0.036
大甲虫	活动密度	8.07	0.006	1.98	0.185	0.51	0.612
	物种丰富度	5.29	0.022	2.91	0.114	0.53	0.599
中甲虫	活动密度	5.69	0.018	1.00	0.337	0.81	0.467
	物种丰富度	5.24	0.023	0.01	0.921	0.54	0.598
小甲虫	活动密度	13.64	<0.001	24.92	<0.001	3.64	0.058
	物种丰富度	5.07	0.025	8.07	0.015	1.87	0.197

指标		对照（CM）		生态修复（ER）		CM × ER
指标		F_2,18	P	F_1,18	P	F_2,18	P
群落结构	活动密度	16.88	<0.001	30.63	<0.001	6.93	0.010
	物种丰富度	29.46	<0.001	15.36	0.002	4.73	0.031
	多样性指数	6.14	0.015	0.14	0.712	4.43	0.036
大甲虫	活动密度	8.07	0.006	1.98	0.185	0.51	0.612
	物种丰富度	5.29	0.022	2.91	0.114	0.53	0.599
中甲虫	活动密度	5.69	0.018	1.00	0.337	0.81	0.467
	物种丰富度	5.24	0.023	0.01	0.921	0.54	0.598
小甲虫	活动密度	13.64	<0.001	24.92	<0.001	3.64	0.058
	物种丰富度	5.07	0.025	8.07	0.015	1.87	0.197

地表甲虫		海拔	坡度	草本盖度	土壤有机碳
群落结构	活动密度	-0.17	0.04	-0.61^**	-0.22
	物种丰富度	-0.64^**	0.33	-0.47^*	-0.04
	多样性指数	-0.53^*	0.61^**	-0.19	0.28
大甲虫	活动密度	-0.72^***	0.72^***	-0.20	-0.04
	物种丰富度	-0.52^*	0.44⁺	-0.36	0.03
中甲虫	活动密度	-0.62^**	0.36	0.02	0.39
	物种丰富度	-0.65^**	0.46⁺	-0.11	0.17
小甲虫	活动密度	-0.03	-0.03	-0.68^**	-0.26
	物种丰富度	-0.28	0.23	-0.55^*	-0.14