The Norwegian Institute for Water Research (NIVA) , NO-0349 Oslo , Norway.
Swedish University of Agricultural Sciences (SLU) , 750 07 Uppsala , Sweden.
Environ Sci Technol. 2019 Feb 19;53(4):1834-1843. doi: 10.1021/acs.est.8b06399. Epub 2019 Jan 29.
Temporally (1965-2015) and spatially (55°-70°N) extensive records of total mercury (Hg) in freshwater fish showed consistent declines in boreal and subarctic Fennoscandia. The database contains 54 560 fish entries ( n: pike > perch ≫ brown trout > roach ≈ Arctic charr) from 3132 lakes across Sweden, Finland, Norway, and Russian Murmansk area. 74% of the lakes did not meet the 0.5 ppm limit to protect human health. However, after 2000 only 25% of the lakes exceeded this level, indicating improved environmental status. In lakes where local pollution sources were identified, pike and perch Hg concentrations were significantly higher between 1965 and 1990 compared to values after 1995, likely an effect of implemented reduction measures. In lakes where Hg originated from long-range transboundary air pollution (LRTAP), consistent Hg declines (3-7‰ per year) were found for perch and pike in both boreal and subarctic Fennoscandia, suggesting common environmental controls. Hg in perch and pike in LRTAP lakes showed minimal declines with latitude, suggesting that drivers affected by temperature, such as growth dilution, counteracted Hg loading and food web exposure. We recommend that future fish Hg monitoring sampling design should include repeated sampling and collection of pollution history, water chemistry, fish age, and stable isotopes to enable evaluation of emission reduction policies.
在时间(1965-2015 年)和空间(55°-70°N)上,北欧和北亚富氧区淡水鱼的总汞(Hg)记录广泛减少。该数据库包含来自瑞典、芬兰、挪威和俄罗斯摩尔曼斯克地区 3132 个湖泊的 54560 个鱼类样本(n:梭鲈>鲈鱼>鳟鱼>欧鲫≈北极红点鲑)。74%的湖泊未达到 0.5ppm 的限值,无法保护人类健康。然而,2000 年后,只有 25%的湖泊超过这一水平,表明环境状况有所改善。在确定了当地污染源的湖泊中,1965 年至 1990 年间梭鲈和鲈鱼的 Hg 浓度明显高于 1995 年后的值,这可能是实施减排措施的结果。在汞源为长距离越境空气污染(LRTAP)的湖泊中,北欧和北亚富氧区的鲈鱼和梭鲈的 Hg 浓度均呈持续下降趋势(每年 3-7‰),表明存在共同的环境控制因素。LRTAP 湖泊中鲈鱼和梭鲈的 Hg 浓度随纬度的变化最小,这表明受温度影响的驱动因素(如生长稀释)抵消了 Hg 负荷和食物网暴露。我们建议,未来鱼类 Hg 监测采样设计应包括重复采样和收集污染历史、水化学、鱼类年龄和稳定同位素,以评估减排政策。
