Arsenic-Uranium Distribution Characteristics and Risk Assessment in the Aquatic Environment of Hailar Basin

doi:10.19657/j.geoscience.1000-8527.2022.020

Abstract

Abstract:

The Hailar Basin is located in an arid to semi-arid region, and its water resource has received widespread attention. Studying the hydrogeochemical characteristics of the local water environment and health risk assessment is conducive to better protection and utilization of water resource. Based on field sampling data, we analyzed its hydrochemical characteristics and influence factors, used the PHREEQC software to simulate the As-U occurrence, and conducted characteristic analysis and risk assessment of As-U co-pollution phenomena. The results show that the As-U concentrations in the local water environment mostly exceed the World Health Organization (WHO) standard limits. The As concentration in the water environment in the Beier Lake Depression-Cuogang Uplift is higher, and the U concentration in the Cuogang Uplift near Hulun Lake is higher. Calculated by the US EPA health risk assessment model, the average non-carcinogenic total risk HI_total of different populations all exceed the acceptable level (HI_total <1), and the average carcinogenic risk of As also exceeds the acceptable level (1×10^-6). The total non-carcinogenic risk and carcinogenic risk: children>female adult>male adult. The PHREEQC simulation results show that As in the water environment mainly exists in the form of As(V), and most of the sampling spots are dominated by $HAsO 4 2 -$ and H₂ $AsO 4 -$ . Uranium occurs mainly in the form of U(VI): UO₂(CO₃) $3 4 -$ and UO₂(CO₃) $2 2 -$ . The chemical valence of As is readily affec-ted by the pH and Eh values. The pH decrease and the more toxic As(III) are likely formed under relatively reducing conditions. The chemical valence of U is not strongly affected by the pH and Eh values, but changing which would also form solid deposits such as bituminous uranium ore, which may cause stones and other related diseases.

Key words: arsenic, uranium, distribution characteristics, occurrence mode, health risk, Hailar basin

CLC Number:

P641.12

LIU Shengfeng, GAO Bai, YI Ling, FANG Zheng, SHI Tiancheng, DING Yan. Arsenic-Uranium Distribution Characteristics and Risk Assessment in the Aquatic Environment of Hailar Basin[J]. Geoscience, 2023, 37(04): 933-942.

Figures/Tables 9

Fig.1 Distribution of sampling locations

Table 1 Characteristics of water quality indicators in the Hailar Basin

水样类型	项目	pH	TDS	Eh	K⁺	Na⁺	Ca²⁺	Mg²⁺	Cl^-	$SO 4 2 -$	$NO 3 -$	$HCO 3 -$	Fe²⁺	Fe³⁺	As	U
地表水	最小值	8.16	255.00	163.00	4.57	38.70	23.94	17.49	13.60	4.29	0.00	345.43	0.078	0.086	0.024	0.018
	最大值	9.88	1080.00	238.00	15.06	251.85	38.45	64.65	97.97	32.68	0.32	673.94	0.160	0.743	0.102	0.135
	平均值	8.94	648.75	191.25	10.67	166.15	29.47	39.02	59.08	17.93	0.08	467.51	0.112	0.344	0.060	0.072
	标准差	0.66	351.45	29.34	3.87	88.33	5.85	17.05	31.97	13.52	0.14	123.68	0.030	0.244	0.033	0.044
	变异系数	0.07	0.54	0.15	0.36	0.53	0.20	0.44	0.54	0.75	1.73	0.26	0.272	0.710	0.542	0.609
地下水	最小值	7.12	244.00	-133.00	0.67	12.87	5.79	5.23	4.16	4.17	0.00	90.04	0.029	0.085	0.005	0.017
	最大值	8.63	3690.00	329.00	49.17	625.79	123.11	164.03	909.33	417.82	32.81	803.11	0.131	4.477	0.123	0.257
	平均值	7.77	1195.44	188.52	7.77	5.28	240.83	49.85	224.41	97.44	7.59	405.36	0.052	0.411	0.036	0.075
	标准差	0.34	819.06	100.86	7.98	175.62	26.62	28.78	230.55	94.47	6.96	160.13	0.023	0.854	0.025	0.048
	变异系数	0.04	0.69	0.54	1.51	0.73	0.53	0.68	1.03	0.97	0.92	0.40	0.436	2.080	0.689	0.637

Table 1 Characteristics of water quality indicators in the Hailar Basin

水样类型	项目	pH	TDS	Eh	K⁺	Na⁺	Ca²⁺	Mg²⁺	Cl^-	$SO 4 2 -$	$NO 3 -$	$HCO 3 -$	Fe²⁺	Fe³⁺	As	U
地表水	最小值	8.16	255.00	163.00	4.57	38.70	23.94	17.49	13.60	4.29	0.00	345.43	0.078	0.086	0.024	0.018
	最大值	9.88	1080.00	238.00	15.06	251.85	38.45	64.65	97.97	32.68	0.32	673.94	0.160	0.743	0.102	0.135
	平均值	8.94	648.75	191.25	10.67	166.15	29.47	39.02	59.08	17.93	0.08	467.51	0.112	0.344	0.060	0.072
	标准差	0.66	351.45	29.34	3.87	88.33	5.85	17.05	31.97	13.52	0.14	123.68	0.030	0.244	0.033	0.044
	变异系数	0.07	0.54	0.15	0.36	0.53	0.20	0.44	0.54	0.75	1.73	0.26	0.272	0.710	0.542	0.609
地下水	最小值	7.12	244.00	-133.00	0.67	12.87	5.79	5.23	4.16	4.17	0.00	90.04	0.029	0.085	0.005	0.017
	最大值	8.63	3690.00	329.00	49.17	625.79	123.11	164.03	909.33	417.82	32.81	803.11	0.131	4.477	0.123	0.257
	平均值	7.77	1195.44	188.52	7.77	5.28	240.83	49.85	224.41	97.44	7.59	405.36	0.052	0.411	0.036	0.075
	标准差	0.34	819.06	100.86	7.98	175.62	26.62	28.78	230.55	94.47	6.96	160.13	0.023	0.854	0.025	0.048
	变异系数	0.04	0.69	0.54	1.51	0.73	0.53	0.68	1.03	0.97	0.92	0.40	0.436	2.080	0.689	0.637

Fig.2 Piper diagram for water samples form the study area

Table 2 Arsenic and uranium contents in surface water sampling spots

地表水采样编号	采样点经度	采样点纬度	砷(mg/L)	铀(mg/L)
H1	118°47'05″	48°45'09″	0.082	0.018
H2	117°43'12″	47°58'09″	0.024	0.048
H3	118°11'26″	48°13'12″	0.033	0.087
H4	118°09'28″	48°23'28″	0.102	0.135

Fig.3 Contour map of arsenic-uranium contents in groundwater

Fig.4 Gibbs diagram for water samples from the study area

Fig.5 Health risk assessment of different populations

Fig.6 Main occurrence forms of As and U in water samples from the study area

Fig.7 Relationship between As and U under different pH and Eh values [37-38]

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