钦州湾全氟/多氟烷基化合物的污染特征及生态风险评估

doi:10.16258/j.cnki.1674-5906.2025.07.003

生态环境学报 ›› 2025, Vol. 34 ›› Issue (7): 1020-1028.DOI: 10.16258/j.cnki.1674-5906.2025.07.003

• “新污染物”研究专栏 • 上一篇下一篇

钦州湾全氟/多氟烷基化合物的污染特征及生态风险评估

田蜜¹^,²(), 廖日权³, 张健², 董凤凤⁴, 唐建辉²^,³^,^*()

1.聊城大学地理与环境学院，山东聊城 252000
2.中国科学院烟台海岸带研究所/海岸带环境过程与生态修复重点研究室，山东烟台 264003
3.北部湾大学海洋学院/广西北部湾海洋环境变化与灾害研究重点实验室/平陆运河河口海湾生态系统广西野外科学观测研究站，广西钦州 535011
4.上海交通大学环境科学与工程学院，上海 200240

收稿日期:2025-02-02 出版日期:2025-07-18 发布日期:2025-07-11
通讯作者: *E-mail: jhtang@yic.ac.cn
作者简介:田蜜（1999年生），女，硕士研究生，研究方向为地理学。E-mail: v15735574514@163.com
基金资助:
国家自然科学基金区域（山东）创新发展联合基金(U22A20607)

Pollution Characteristics and Ecological Risk Assessment of Per- and Poly-fluoroalkyl Substances (PFAS) in Qinzhou Bay

TIAN Mi¹^,²(), LIAO Riquan³, ZHANG Jian², DONG Fengfeng⁴, TANG Jianhui²^,³^,^*()

1. School of Geography and Environment, Liaocheng University, Liaocheng 252000, P. R. China
2. CAS Key Laboratory of Coastal Environmental Processes and Ecological Remediation/Yantai Institute of Coastal Zone Research, Chinese Academy of Sciences, Yantai 264003, P. R. China
3. Pinglu Canal and Beibu Gulf Coastal Ecosystem Observation and Research Station of Guangxi/Guangxi Key Laboratory of Marine Environmental Change amd Disaster in Beibu Gulf/School of Marine Science, Beibu Gulf University, Qinzhou 535011, P. R. China
4. School of Environmental Science and Engineering, Shanghai Jiao Tong University, Shanghai 200240, P. R. China

Received:2025-02-02 Online:2025-07-18 Published:2025-07-11

摘要/Abstract

摘要：

钦州湾位于北部湾顶部，由北部的茅尾海和南部的外湾组成，是典型的亚热带河口型海湾，拥有红树林、盐沼、海草床和牡蛎礁等典型海洋生态系统。全氟/多氟烷基化合物（PFAS）是典型的新污染物，具有生物毒性且不易降解。为阐明该区域PFAS的污染状况及其对海洋生态系统的影响，分析了钦州湾海水中36种PFAS，并采用熵值法（RQ）评估了全氟辛酸（PFOA）和全氟辛烷磺酸（PFOS）的生态风险。结果表明，PFAS总质量浓度范围是4.57-13.55 ng·L⁻¹，在国内海湾中处于中低水平。六氟环氧丙烷二聚体（HFPO-DA）、六氟环氧丙烷三聚体（HFPO-TA（C7））和全氟丁酸（PFBA）是3种主要的PFAS。空间分布结果表明：茅尾海表层海水中PFAS总浓度由西向东递减，而底层海水中PFAS总浓度的空间分布特征与之相反；外湾表层海水中PFAS总浓度从东北沿岸近三娘湾处向西南方向递减，底层海水中东南区域PFAS的总浓度较低。Spearman相关分析结果表明表层海水中全氟-2-甲氧基乙酸（PFMOAA）和全氟-3,5,7-三氧基辛酸（PFO3OA）可能具有共同的来源。通过生态风险评估，PFOS和PFOA在钦州湾海洋生态系统中呈现出低风险。目前缺乏HFPO-DA和HFPO-TA（C7）的毒理数据，鉴于其较高的浓度水平，亟需进一步研究评估其生态风险。

关键词: 全氟/多氟烷基化合物, 六氟环氧丙烷二聚体, 亚热带海湾, 分布特征, 生态风险评估

Abstract:

Qinzhou Bay, situated at the northern extremity of the Beibu Gulf, encompasses the Maowei Sea to the north and the outer bay to the south. It is a typical subtropical estuarine bay characterized by distinct marine ecosystems, such as mangroves, salt marshes, seagrass, and oyster reefs. Per- and polyfluoroalkyl substances (PFAS) are emerging contaminants that are toxic to ecosystems and persist in their environment. This study aimed to understand the pollution status of PFAS in this region and their ecological risks to marine ecosystems. 36 PFAS were detected and analyzed in the surface and bottom seawater samples, and the ecological risk assessment of perfluorooctanoic acid (PFOA) and perfluorooctane sulfonic acid (PFOS) was performed using the risk quotient (RQ) method. The results showed that the total concentration of PFAS (∑PFAS) ranged from 4.57 to 13.55 ng·L⁻¹, which was at a medium to low levels among coastal bays in China. Hexafluoropropylene oxide dimer acid (HFPO-DA), 2-[2-(trifluoromethoxy) hexafluoropropoxy] tetrafluoropropanoic acid (HFPO-TA (C7)), and perfluorobutanoic acid (PFBA) are the three dominant pollutants. The spatial distribution findings suggested that the ∑PFAS in the surface seawater of the Maowei Sea exhibited a decreasing trend from the western region towards the eastern coastal area. Conversely, ∑PFAS in the bottom seawater showed an opposite trend. In the outer bay, the ∑PFAS in the surface seawater decreased from the northeastern coast near Sanniang Bay to the southwest, whereas the concentration in the southeastern region of the bottom seawater remained relatively low. Spearman correlation analysis suggested that perfluoro-2-methoxyacetic acid (PFMOAA) and perfluoro (3,5,7-trioxaoctanoic) acid (PFO3OA) in the surface seawater may originated from a common source. Furthermore, the ecological risk assessment revealed that the mean RQ values of PFOS and PFOA were far below the threshold of 0.1, indicating low risk to the marine ecosystem of Qinzhou Bay. Considering the high levels and deficiency of ecotoxicological data for HFPO-DA and HFPO-TA (C7), it is necessary to investigate the environmental behaviors and ecotoxicological effects of these emerging PFAS.

Key words: PFAS, HFPO-DA, subtropical bay, distribution characteristics, ecological risk assessment

中图分类号:

X55
X820.4

田蜜, 廖日权, 张健, 董凤凤, 唐建辉. 钦州湾全氟/多氟烷基化合物的污染特征及生态风险评估[J]. 生态环境学报, 2025, 34(7): 1020-1028.

TIAN Mi, LIAO Riquan, ZHANG Jian, DONG Fengfeng, TANG Jianhui. Pollution Characteristics and Ecological Risk Assessment of Per- and Poly-fluoroalkyl Substances (PFAS) in Qinzhou Bay[J]. Ecology and Environmental Sciences, 2025, 34(7): 1020-1028.

图/表 8

参考文献 29

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站位	水层	纬度/°	经度/°	采样时间	水深/m	温度/℃	pH	盐度/‰
茅尾海1	表层	108.55°N	21.87°E	2023-10-14	2.5	26.1	8.0	3.2
茅尾海1	底层	108.55°N	21.87°E	2023-10-14	2.5	25.9	8.1	11.0
茅尾海2	表层	108.51°N	21.83°E	2023-10-14	4.5	25.6	8.0	11.9
茅尾海5	表层	108.54°N	21.82°E	2023-10-14	24	25.4	8.2	10.7
茅尾海5	底层	108.54°N	21.82°E	2023-10-14	24	26.1	9.3	12.6
茅尾海3	表层	108.57°N	21.83°E	2023-10-14	13.7	26.6	8.5	9.8
茅尾海3	底层	108.57°N	21.83°E	2023-10-14	13.7	25.9	8.1	11.0
茅尾海4	表层	108.55°N	21.79°E	2023-10-13	21.9	26.2	8.2	19.1
茅尾海4	底层	108.55°N	21.79°E	2023-10-13	21.9	25.9	8.2	21.0
湾口	表层	108.57°N	21.73°E	2023-10-13	9.5	26.1	8.3	19.9
湾口	底层	108.57°N	21.73°E	2023-10-13	9.5	26.3	8.3	25.7
外湾1	表层	108.59°N	21.67°E	2023-10-14	6.4	26.2	8.3	24.1
外湾1	底层	108.59°N	21.67°E	2023-10-14	6.4	25.8	8.3	27.1
外湾2	表层	108.57°N	21.60°E	2023-10-12	7.1	25.4	8.2	27.9
外湾2	底层	108.57°N	21.60°E	2023-10-12	7.1	26.0	8.5	28.3
外湾3	表层	108.51°N	21.54°E	2023-10-12	6.7	26.3	8.5	30.9
外湾3	底层	108.51°N	21.54°E	2023-10-12	6.7	26.6	8.5	32.0
外湾4	表层	108.65°N	21.60°E	2023-10-13	5.0	26.2	8.4	28.5
外湾4	底层	108.65°N	21.60°E	2023-10-13	5.0	26.0	8.4	29.7
外湾5	表层	108.71°N	21.59°E	2023-10-13	6.3	25.4	8.3	30.8
外湾5	底层	108.71°N	21.59°E	2023-10-13	6.3	26.2	8.3	31.7
外湾6	表层	108.73°N	21.54°E	2023-10-12	11.9	27.4	8.6	32.2
外湾6	底层	108.73°N	21.54°E	2023-10-12	11.9	27.0	8.6	32.4
外湾7	表层	108.63°N	21.53°E	2023-10-12	8.4	26.4	8.5	30.6
外湾7	底层	108.63°N	21.53°E	2023-10-12	8.4	26.6	8.5	31.7
外湾8	表层	108.56°N	21.48°E	2023-10-12	9.7 9.7	25.9	8.2	31.0
外湾8	底层	108.56°N	21.48°E	2023-10-12	9.7 9.7	26.6	8.4	31.3
外湾9	表层	108.63°N	21.49°E	2023-10-12	10.3	26.6	8.4	31.3
外湾9	底层	108.63°N	21.49°E	2023-10-12	10.3	26.9	8.5	32.1
外湾10	表层	108.68°N	21.52°E	2023-10-12	9.5	27.1	8.6	32.1
外湾10	底层	108.68°N	21.52°E	2023-10-12	9.5	27.1	8.6	32.5

站位	水层	纬度/°	经度/°	采样时间	水深/m	温度/℃	pH	盐度/‰
茅尾海1	表层	108.55°N	21.87°E	2023-10-14	2.5	26.1	8.0	3.2
茅尾海1	底层	108.55°N	21.87°E	2023-10-14	2.5	25.9	8.1	11.0
茅尾海2	表层	108.51°N	21.83°E	2023-10-14	4.5	25.6	8.0	11.9
茅尾海5	表层	108.54°N	21.82°E	2023-10-14	24	25.4	8.2	10.7
茅尾海5	底层	108.54°N	21.82°E	2023-10-14	24	26.1	9.3	12.6
茅尾海3	表层	108.57°N	21.83°E	2023-10-14	13.7	26.6	8.5	9.8
茅尾海3	底层	108.57°N	21.83°E	2023-10-14	13.7	25.9	8.1	11.0
茅尾海4	表层	108.55°N	21.79°E	2023-10-13	21.9	26.2	8.2	19.1
茅尾海4	底层	108.55°N	21.79°E	2023-10-13	21.9	25.9	8.2	21.0
湾口	表层	108.57°N	21.73°E	2023-10-13	9.5	26.1	8.3	19.9
湾口	底层	108.57°N	21.73°E	2023-10-13	9.5	26.3	8.3	25.7
外湾1	表层	108.59°N	21.67°E	2023-10-14	6.4	26.2	8.3	24.1
外湾1	底层	108.59°N	21.67°E	2023-10-14	6.4	25.8	8.3	27.1
外湾2	表层	108.57°N	21.60°E	2023-10-12	7.1	25.4	8.2	27.9
外湾2	底层	108.57°N	21.60°E	2023-10-12	7.1	26.0	8.5	28.3
外湾3	表层	108.51°N	21.54°E	2023-10-12	6.7	26.3	8.5	30.9
外湾3	底层	108.51°N	21.54°E	2023-10-12	6.7	26.6	8.5	32.0
外湾4	表层	108.65°N	21.60°E	2023-10-13	5.0	26.2	8.4	28.5
外湾4	底层	108.65°N	21.60°E	2023-10-13	5.0	26.0	8.4	29.7
外湾5	表层	108.71°N	21.59°E	2023-10-13	6.3	25.4	8.3	30.8
外湾5	底层	108.71°N	21.59°E	2023-10-13	6.3	26.2	8.3	31.7
外湾6	表层	108.73°N	21.54°E	2023-10-12	11.9	27.4	8.6	32.2
外湾6	底层	108.73°N	21.54°E	2023-10-12	11.9	27.0	8.6	32.4
外湾7	表层	108.63°N	21.53°E	2023-10-12	8.4	26.4	8.5	30.6
外湾7	底层	108.63°N	21.53°E	2023-10-12	8.4	26.6	8.5	31.7
外湾8	表层	108.56°N	21.48°E	2023-10-12	9.7 9.7	25.9	8.2	31.0
外湾8	底层	108.56°N	21.48°E	2023-10-12	9.7 9.7	26.6	8.4	31.3
外湾9	表层	108.63°N	21.49°E	2023-10-12	10.3	26.6	8.4	31.3
外湾9	底层	108.63°N	21.49°E	2023-10-12	10.3	26.9	8.5	32.1
外湾10	表层	108.68°N	21.52°E	2023-10-12	9.5	27.1	8.6	32.1
外湾10	底层	108.68°N	21.52°E	2023-10-12	9.5	27.1	8.6	32.5

PFAS	表层水（n=16）				底层水（n=16）
PFAS	均值/(ng·L⁻¹)	范围/(ng·L⁻¹)	检出率/%	百分比/%	均值/(ng·L⁻¹)	范围/(ng·L⁻¹)	检出率/%	百分比/%
PFBA	1.21±0.46	0.85-2.45	100	14.15	1.34±0.88	0.58-3.64	100	16.01
PFPeA	0.05±0.08	n.d.-0.2	31	0.63	0.06±0.07	n.d.-0.17	47	0.73
PFHxA	0.34±0.08	0.23-0.5	100	3.99	0.32±0.12	0.17-0.59	100	3.8
PFHpA	0.15±0.17	n.d.-0.5	50	1.77	0.23±0.2	n.d.-0.72	87	2.73
PFOA	0.27±0.53	n.d.-2.02	50	3.2	0.32±0.48	n.d.-1.59	60	3.77
PFNA	0.22±0.15	n.d.-0.53	88	2.56	0.12±0.1	n.d.-0.41	80	1.4
PFDA	0.04±0.02	n.d.-0.08	94	0.41	0.03±0.03	n.d.-0.1	87	0.3
PFUnDA	0.004±0.01	n.d.-0.05	13	0.05	0.01±0.02	n.d.-0.1	27	0.13
PFDoDA	0.03±0.08	n.d.-0.31	13	0.31	0.01±0.03	n.d.-0.08	20	0.12
PFBS	0.27±0.1	n.d.-0.43	94	3.11	0.27±0.1	n.d.-0.42	93	3.22
PFHxS	0.04±0.02	n.d.-0.07	81	0.43	0.03±0.03	n.d.-0.09	93	0.37
PFOS	0.74±0.76	n.d.-2.08	63	8.67	0.36±0.81	n.d.-2.66	27	4.35
6:2H-PFESA	0.004±0.01	n.d.-0.02	44	0.05	0.18±0.7	n.d.-2.72	33	2.19
6:2Cl-PFESA	0.004±0.01	n.d.-0.04	44	0.05	0.25±0.73	n.d.-2.66	27	3.05
4:2 FTSA	0.03±0.06	n.d.-0.26	50	0.39	0.03±0.11	n.d.-0.41	20	0.41
HFPO-DA	2.57±0.48	1.76-3.35	100	30.11	2.5±0.75	1.1-3.8	100	29.86
HFPO-TA(C7)	1.94±1.51	n.d.-5.4	81	22.67	1.75±0.67	n.d.-2.65	93	20.98
HFPO-TA(C8)	0.05±0.1	n.d.-0.37	38	0.53	0.07±0.09	n.d.-0.34	60	0.8
HFPO-TA(C9)	0.15±0.53	n.d.-2.12	38	1.73	0.03±0.07	n.d.-0.27	40	0.4
PFMOAA	0.16±0.07	0.06-0.3	100	1.89	0.16±0.03	0.12-0.22	100	1.92
PFO2HxA	0.11±0.12	n.d.-0.35	56	1.3	0.13±0.11	n.d.-0.31	60	1.56
PFO3OA	0.07±0.04	0.02-0.18	100	0.79	0.07±0.02	0.03-0.1	100	0.79
PFO5DoDA	0.02±0.03	n.d.-0.08	38	0.2	0.002±0.002	n.d.-0.01	33	0.02
PFO2OA	0.08±0.11	n.d.-0.27	44	0.97	0.09±0.14	n.d.-0.47	47	1.1

PFAS	表层水（n=16）				底层水（n=16）
PFAS	均值/(ng·L⁻¹)	范围/(ng·L⁻¹)	检出率/%	百分比/%	均值/(ng·L⁻¹)	范围/(ng·L⁻¹)	检出率/%	百分比/%
PFBA	1.21±0.46	0.85-2.45	100	14.15	1.34±0.88	0.58-3.64	100	16.01
PFPeA	0.05±0.08	n.d.-0.2	31	0.63	0.06±0.07	n.d.-0.17	47	0.73
PFHxA	0.34±0.08	0.23-0.5	100	3.99	0.32±0.12	0.17-0.59	100	3.8
PFHpA	0.15±0.17	n.d.-0.5	50	1.77	0.23±0.2	n.d.-0.72	87	2.73
PFOA	0.27±0.53	n.d.-2.02	50	3.2	0.32±0.48	n.d.-1.59	60	3.77
PFNA	0.22±0.15	n.d.-0.53	88	2.56	0.12±0.1	n.d.-0.41	80	1.4
PFDA	0.04±0.02	n.d.-0.08	94	0.41	0.03±0.03	n.d.-0.1	87	0.3
PFUnDA	0.004±0.01	n.d.-0.05	13	0.05	0.01±0.02	n.d.-0.1	27	0.13
PFDoDA	0.03±0.08	n.d.-0.31	13	0.31	0.01±0.03	n.d.-0.08	20	0.12
PFBS	0.27±0.1	n.d.-0.43	94	3.11	0.27±0.1	n.d.-0.42	93	3.22
PFHxS	0.04±0.02	n.d.-0.07	81	0.43	0.03±0.03	n.d.-0.09	93	0.37
PFOS	0.74±0.76	n.d.-2.08	63	8.67	0.36±0.81	n.d.-2.66	27	4.35
6:2H-PFESA	0.004±0.01	n.d.-0.02	44	0.05	0.18±0.7	n.d.-2.72	33	2.19
6:2Cl-PFESA	0.004±0.01	n.d.-0.04	44	0.05	0.25±0.73	n.d.-2.66	27	3.05
4:2 FTSA	0.03±0.06	n.d.-0.26	50	0.39	0.03±0.11	n.d.-0.41	20	0.41
HFPO-DA	2.57±0.48	1.76-3.35	100	30.11	2.5±0.75	1.1-3.8	100	29.86
HFPO-TA(C7)	1.94±1.51	n.d.-5.4	81	22.67	1.75±0.67	n.d.-2.65	93	20.98
HFPO-TA(C8)	0.05±0.1	n.d.-0.37	38	0.53	0.07±0.09	n.d.-0.34	60	0.8
HFPO-TA(C9)	0.15±0.53	n.d.-2.12	38	1.73	0.03±0.07	n.d.-0.27	40	0.4
PFMOAA	0.16±0.07	0.06-0.3	100	1.89	0.16±0.03	0.12-0.22	100	1.92
PFO2HxA	0.11±0.12	n.d.-0.35	56	1.3	0.13±0.11	n.d.-0.31	60	1.56
PFO3OA	0.07±0.04	0.02-0.18	100	0.79	0.07±0.02	0.03-0.1	100	0.79
PFO5DoDA	0.02±0.03	n.d.-0.08	38	0.2	0.002±0.002	n.d.-0.01	33	0.02
PFO2OA	0.08±0.11	n.d.-0.27	44	0.97	0.09±0.14	n.d.-0.47	47	1.1

指标	PNEC/ (ng·L⁻¹)	MEC/(ng·L⁻¹)			RQ/10⁻³
指标	PNEC/ (ng·L⁻¹)	Max	Mean	Min	Max	Mean	Min
表层海水
PFOS	300	2.08	0.74	0	0.007	0.002	0
PFOA	300	2.02	0.27	0	0.007	0.001	0
底层海水
PFOS	300	2.66	0.36	0	0.009	0.001	0
PFOA	300	1.59	0.32	0	0.005	0.001	0

钦州湾全氟/多氟烷基化合物的污染特征及生态风险评估

Pollution Characteristics and Ecological Risk Assessment of Per- and Poly-fluoroalkyl Substances (PFAS) in Qinzhou Bay

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