Source Analysis and Ecological Risk Assessment of Heavy Metals in Sediments of Taojia Lake

doi:10.11988/ckyyb.20231299

Abstract

Abstract:

Core sediment samples collected from three distinct areas of Taojia Lake in Songzi County, Hubei Province, were tested for heavy metals including copper (Cu), zinc (Zn), chromium (Cr), nickel (Ni), lead (Pb), and arsenic (As), as well as grain size. The contamination status was assessed using the potential ecological risk index (RI), enrichment factor (EF), and geo-accumulation index (Igeo). Sources of these contaminants were traced through correlation analysis and positive matrix factorization (PMF) modeling. Results indicated that 1) Heavy metal contamination was most severe in the central area of the lake, followed by those in lakeshore and riparian zone in descending order. As depth increased, the contamination at lakeshore alleviated, but aggravated in the central area and the riparian zone. 2) Among the tested heavy metals, arsenic (As) and chromium (Cr) showed the most severe contamination, with As of light contamination and Cr mild-to-moderate contamination. Copper (Cu), zinc (Zn), nickel (Ni), and lead (Pb) exhibited less pollution. 3) Correlation analysis and PMF modeling revealed that heavy metals in the sediments primarily originated from mining activities (18.8%), natural sources (52.4%), and agricultural and industrial activities (28.8%). Specifically, Cu was mainly derived from mining activities, Pb from natural sources, and As from agricultural and industrial activities. Zinc (Zn), nickel (Ni), and Cr were influenced by all three sources. 4) Hydrodynamic conditions and human activities have led to spatial variations in heavy metal distribution in Taojia Lake. The strong hydrodynamics in the riparian zone have diluted heavy metal concentrations, resulting in lower heavy metal levels compared to the lakeshore and the central area. Changes in hydrodynamic conditions affected the vertical distribution of Pb and Ni. Variations in the distribution of Cu and Zn are primarily attributed to mining industrial activities, while annual increases in As levels were linked to agricultural activities.

Key words: sediment, heavy metals, pollution assessment, ecological risk, source analysis

XIAO Shang-bin, GONG Zhe, LIU Jia, LI Shi-jian, HE Wen-cheng, ZHU Liang-chen, ZHENG Yi-ge. Source Analysis and Ecological Risk Assessment of Heavy Metals in Sediments of Taojia Lake[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(2): 44-53.

Figures/Tables 10

Fig.1 Location of sampling sites in Taojia Lake

Table 1 Assessment criterion for potential ecologicalrisks[18]

Erⁱ	RI	潜在生态危害程度	Erⁱ	RI	潜在生态危害程度
<40	<150	轻微	[160,320)	≥600	很强
[40,80)	[150,300)	中等	≥320		极强
[80,160)	[300,600)	强

Table 2 Rating of geo-accumulation index

I_geo	分级	污染程度	I_geo	分级	污染程度
≤0	0	无	(3,4]	4	偏重度
(0,1]	1	轻度	(4,5]	5	重度
(1,2]	2	偏中度	>5	6	严重
(2,3]	3	中度

Fig.2 Grain size characteristics of sediment cores taken from Taojia Lake

Fig.3 Vertical distribution of heavy metals in sediment cores taken from Taojia Lake

Table 3 Statistics heavy metal content in lakes of HubeiProvince in literaturemg/kg

湖泊	Cu	Pb	Zn	Ni	Cr	As
大冶湖	579	104	476	73	72	266
西洞庭湖	30	27	146	30	50	66
武湖	41	42	113	51	104	16
陶家湖湖岸	48	42	142	62	269	20
陶家湖湖心	43	37	144	61	284	25
陶家湖消落带	52	29	148	56	236	26

Fig.4 Vertical distribution of ecological risk index(RI) of heavy metals in sediment cores taken from Taojia Lake

Fig.5 Heatmap of geo-accumulation index of heavy metals in sediment cores taken from Taojia Lake

Fig.6 Correlation analysis between heavy metal concentrations and sediment grain size

Fig.7 Contribution rate of each source factor to heavy metal concentration in sediment cores taken from Taojia Lake

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