Abstract
Metals are important chemicals occurring in various ecosystems. Some of them are toxic, some are toxic when appearing in excess and some are essential for the environment and human health. They are ubiquitous constituents of various natural materials in the lithosphere, the hydrosphere and the biosphere.
High-temperature processes in the primary non-ferrous metal industries are the major source of atmospheric arsenic (As), cadmium (Cd), copper (Cu), indium (In), antimony (Sb), and zinc (Zn), and an important source of lead (Pb) and selenium (Se). Combustion of coal in electric power plants and industrial, commercial, and residential burners is the major source of anthropogenic mercury (Hg), molybdenum (Mo), and selenium and a significant source of arsenic, chromium (Cr), manganese (Mn), antimony, and thallium (Tl). Combustion of oil for the same purpose is the most important source of vanadium (V) and nickel (Ni). Combustion of leaded gasoline is estimated to be the major source of lead. Atmospheric chromium and manganese derive primarily from the iron and steel industry. The largest discharges of these metals are estimated for soils followed by discharges to water.
The degree of human alteration of metals biogeochemical cycles caused by their anthropogenic emissions affects human health impacts of these chemicals. The information on alteration degree on global and regional scale is discussed.
Emissions of metals from various anthropogenic sources can be reduced using technological (e.g. Best Available Technology (BAT) solutions) and non-technological measures (e.g. Best Environment Practice (BEP) option). Various emission reduction measures are presented.
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References
Ackland ML, Silbergeld EK, Bornhorst J, Dedoussis G, Dietert RR, Nriagu JO, Pacyna JM, Pettifor JM (2015) Metals in the environment as risk factor for infectious diseases. In: Nriagu, Skaar ES (eds) Heavy metals and infectious diseases. Ernst Strungmann Forum reports (Lupp J, series ed.), vol 16. MIT Press, Cambridge, MA. ISBN: 978-0-262-02919-3
Andrea MO, Asami T, Bertine KK, Buat-Ménard PE, Duce RA, Filip ZK, Förstner U, Goldberg ED, Heinrichs H, Jernelöv AB, Pacyna JM, Thornton J, Tobschall JJ, Zoller WH (1984) Perturbations of biogeochemical cycles of metals. In: Nriagu JO (ed) Changing metal cycles and human health. Dahlem Konferenzen and Springer, Berlin, Heidelberg, New York, and Tokyo
Baartmans R, van Tongeren W, van der Vlies J, Ullrich S, Mattila T, Cousins AP, Belhaj M, Munthe J, Pacyna JM, Sundseth K (2008) Deliverable D4. DSS handbook SOCOPSE, draft version. Source Control of Priority Substances in Europe (SOCOPSE). TNO, The Netherlands
Chang LW (ed) (1996) Toxicology of metals, vol 1. CRC Press, Boca Raton, FL
De Vos W, Tarvainen T (eds) (2006) Geochemical atlas of Europe. Part 2: Interpretation of geochemical maps, additional table, figures, maps and related publications. Geological Survey of Finland, Espoo
EC (2006) Environmental Code of Practice. Canadian Environmental Protection Act 1999, Base metals smelters and refineries. EPS1/MM/11E, Environment Canada, Gatineau, Canada, Mar 2006
Falkowski P et al (2000) The global carbon cycle: a test of our knowledge of Earth as a system. Science 290(5490):291–296
Hinkley TK (2003) Volcanic emissions of mercury. U S Geol Surv Circ 1248:35–37
Levine JS (ed) (1991) Global biomass burning: atmospheric, climatic and biospheric implications. MIT Press, Cambridge, MA
Nriagu JO (1989) A global assessment of natural sources of atmospheric trace metals. Nature 338:47–49
Nriagu JD, Pacyna JM (1988) Quantitative assessment of worldwide contamination of air, water, and soils by trace elements. Nature 333:134–139
Pacyna JM (1986) Atmospheric trace elements from natural and anthropogenic sources. In: Nriagu JO, Davidson CI (eds) Toxic metals in the atmosphere, Advances in environmental science and technology. Wiley, New York
Pacyna JM (2009) Material flow analysis for selected priority substances. The SOCOPSE project, Report WP2–D2. Norwegian Institute for Air Research, Kjeller
Pacyna JM, Ahmadzai H (1997) Air pollution abatement. In: Brune D, Chapman D, Gwynne M, Pacyna JM (eds) The global environment. Wiley and Scandinavian, Weinheim, pp 724–748
Pacyna JM, Pacyna EG (2001) Assessment of global and regional emissions of trace metals to the atmosphere from anthropogenic sources worldwide. Can J Environ Rev 9:269–298
Pacyna JM, Pacyna EG (2005) Anthropogenic sources and global emissions of mercury. In: MB Parsons, JB Percival (eds) Mercury: sources, measurements, cycles and effects. Short course series, vol 34. Mineralogical Association of Canada, pp 21–41
Pacyna EG, Pacyna JM, Sundseth K, Munthe J, Kindbom K, Wilson S, Steenhausen F, Maxson P (2010a) Global emission of mercury to the atmosphere from anthropogenic sources in 2005 and projections to 2020. Atmos Environ 44:2487–2499
Pacyna JM, Sundseth K, Pacyna EG, Munthe J, Belhaj M, Astrom S (2010b) An assessment of costs and benefits associated with mercury emission reductions from major anthropogenic sources. J Air Waste Manag Assoc 60:302–315
Pacyna JM, Sundseth K, Pacyna EG (2015a) New technologies using trace metals of concern. In: Nriagu JO, Skaar ES (eds) Heavy metals and infectious diseases. Ernst Strungmann Forum reports (Lupp J, series ed), vol. 16. MIT Press, Cambridge, MA. ISBN: 978-0-262-02919-3
Pacyna JM, Sundseth K, Pacyna EG (2015b) Technological and non-technological measures to reduce mercury emissions from industrial sources. The 2014 international conference on mercury as a global pollutant, Jeju, 15–19 June
Rauch JN, Pacyna JM (2009) Earth’s global anthrobiogeochemical Ag, Al, Cr, Cu, Fe, Ni, Pb, and Zn cycles. Global Biogeochem Cycles 23, GB2001. doi:10.1029/2008GB003376
Rytuba JJ (2005) Geogenic and mining sources of mercury to the environment. In: Parsons MB, Percival JB (eds) Mercury: sources, measurements, cycles and effects. Short course series, vol 34. Mineralogical Association of Canada, pp 21–41
Sundseth K (2012) A novel combination of methods developed for decision support on abatement of mercury in Europe. PhD Dissertation, Gdansk University of Technology, Gdansk
Sundseth K, Pacyna JM, Banel A, Pacyna EG, Rautio A (2015) Climate change impacts on environmental and human exposure to mercury in the Arctic. Int J Environ Res Public Health 12:3579–3599. doi:10.3390/ijerph120403579
UNEP (2013a) Environmental challenges of metals cycles. UNEP Resource Panel, United Nations Environment Programme, Geneva
UNEP (2013b) Global mercury assessment 2013: sources, emissions, releases and environmental transport. UNEP Division of Technology, Industry and Economics, United Nations Environment Programme, Geneva
van Storch H, Hagner C, Costa-Cabral M, Feser F, Pacyna JM, Pacyna E, Kolb S (2002) Curbing the omnipresence of lead in the European environment since the 1970’s – a successful example of efficient environmental policy. EOS 83(36):393–399
van Storch H, Costa-Cabral M, Hagner C, Feser F, Pacyna JM, Pacyna EG (2003) Four decades of gasoline lead emissions and control policies in Europe: a retrospective assessment. Sci Total Environ 311:151–176
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Pacyna, J.M., Sundseth, K., Pacyna, E.G. (2016). Sources and Fluxes of Harmful Metals. In: Pacyna, J., Pacyna, E. (eds) Environmental Determinants of Human Health. Molecular and Integrative Toxicology. Springer, Cham. https://doi.org/10.1007/978-3-319-43142-0_1
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DOI: https://doi.org/10.1007/978-3-319-43142-0_1
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