Greenland Ice Evidence of Hemispheric Lead Pollution Two Millennia Ago by Greek and Roman Civilizations

Hong, Sungmin; Candelone, Jean-Pierre; Patterson, Clair C.; Boutron, Claude F.

doi:10.1126/science.265.5180.1841

Cited by 661 publications

(326 citation statements)

References 20 publications

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“…As a matter of fact, great increase in Pb depositions successively highlight the impact of the extensive mining industry during the Greek and Roman periods (from ca 300 BC to AD 400), the Late Middle Ages (ca AD 1400), the Early Modern Europe (after ca 1600), and the Industrial Revolution (after ca 1850). Pre-industrial anthropogenic Pb deposition at high altitude in the Southern Alps strongly resembles that deposited onto the Greenland ice sheet, pointing to the homogeneous pollution of the Northern hemisphere sustained by long-range transport of air pollutants from mid-latitude regions (Hong et al, 1994). Such results are in agreement with the intercontinental transport of Saharan mineral dust that occasionally reaches Summit Greenland (Thevenon et al, 2010b).…”

Section: Discussionsupporting

confidence: 78%

(Pre-) historic changes in natural and anthropogenic heavy metals deposition inferred from two contrasting Swiss Alpine lakes

Thevenon

Guédron

Chiaradia

et al. 2011

Quaternary Science Reviews

110

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a b s t r a c tContinuous high-resolution sedimentary record of heavy metals (chromium (Cr), copper (Cu), lead (Pb), zinc (Zn), manganese (Mn), and mercury (Hg)), from lakes Lucerne and Meidsee (Switzerland), provides pollutant deposition history from two contrasting Alpine environments over the last millennia. The distribution of conservative elements (thorium (Th), scandium (Sc) and titanium (Ti)) shows that in absence of human disturbances, the trace element input is primarily controlled by weathering processes (i.e., runoff and erosion). Nonetheless, the enrichment factor (EF) of Pb and Hg (that are measured by independent methods), and the Pb isotopic composition of sediments from the remote lake Meidsee (which are proportionally more enriched in anthropogenic heavy metals), likely detect early mining activities during the Bronze Age. Meanwhile, the deposition of trace elements remains close to the range of natural variations until the strong impact of Roman activities on atmospheric metal emissions. Both sites display simultaneous increases in anthropogenic trace metal deposition during the Greek and Roman Empires (ca 300 BC to AD 400), the Late Middle Ages (ca AD 1400), and the Early Modern Europe (after ca AD 1600). However, the greatest increases in anthropogenic metal pollution are evidenced after the industrial revolution of ca AD 1850, at low and high altitudes. During the twentieth century, industrial releases multiplied by ca 10 times heavy metal fluxes to hydrological systems located on both sides of the Alps. During the last decades, the recent growing contribution of low radiogenic Pb further highlights the contribution of industrial sources with respect to wood and coal burning emissions.

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Section: Discussionsupporting

confidence: 78%

(Pre-) historic changes in natural and anthropogenic heavy metals deposition inferred from two contrasting Swiss Alpine lakes

Thevenon

Guédron

Chiaradia

et al. 2011

Quaternary Science Reviews

110

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“…Increases in the concentration of both lead (Pb) and copper (Cu) in ice cores recovered from Greenland (8,9) and of antimony (Sb), arsenic (As), and bismuth (Bi) in ice cores from the Canadian Arctic (10,11) caused by anthropogenic activities as early as 500 B.C. have been noted.…”

mentioning

confidence: 99%

“…have been noted. Preindustrial Pb concentration increases in Greenland have been linked to Pb mining and smelting performed in the Mediterranean region during the Greek, Roman, and Medieval periods (8,12), indicating the hemispheric-scale impact of early anthropogenic activities. In contrast, ice cores recovered from midlatitudes provide evidence for anthropogenic aerosol emissions from the late 19th century in the European Alps (13,14) and from the middle of the 20th century in the Himalaya (6,15).…”

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confidence: 99%

Widespread pollution of the South American atmosphere predates the industrial revolution by 240 y

Uglietti

Gabrielli

Cooke

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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In the Southern Hemisphere, evidence for preindustrial atmospheric pollution is restricted to a few geological archives of low temporal resolution that record trace element deposition originating from past mining and metallurgical operations in South America. Therefore, the timing and the spatial impact of these activities on the past atmosphere remain poorly constrained. Here we present an annually resolved ice core record (A.D. 793–1989) from the high-altitude drilling site of Quelccaya (Peru) that archives preindustrial and industrial variations in trace elements. During the precolonial period (i.e., pre-A.D. 1532), the deposition of trace elements was mainly dominated by the fallout of aeolian dust and of ash from occasional volcanic eruptions, indicating that metallurgic production during the Inca Empire (A.D. 1438−1532) had a negligible impact on the South American atmosphere. In contrast, a widespread anthropogenic signal is evident after around A.D. 1540, which corresponds with the beginning of colonial mining and metallurgy in Peru and Bolivia, ∼240 y before the Industrial Revolution. This shift was due to a major technological transition for silver extraction in South America (A.D. 1572), from lead-based smelting to mercury amalgamation, which precipitated a massive increase in mining activities. However, deposition of toxic trace metals during the Colonial era was still several factors lower than 20th century pollution that was unprecedented over the entirety of human history.

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“…Previous environmental studies of pollution from ancient metallurgy have noted the relationship between an increased regional and global output of toxic chemicals and the intensification of production that coincides with the growing political and economic complexity of ancient states and empires (Cooke et al, 2008;Grattan et al, 2007;Hong et al, 1994;Jouffroy-Bapicot et al, 2007;Karlsson et al, 2015;McFarlane et al, 2014;Mighall et al, 2014;Nriagu, 1996). While this is certainly the case in a broad sense, increasingly sophisticated archaeological and environmental methods for geochemical analysis and chronological determinations have opened the doors for more nuanced explanations of landscape degradation that account for coupled human and natural impacts (Romey et al, 2015), site abandonment processes (Iavazzo et al, 2011), and economic and land-use practices (LopezMerino et al, 2014).…”

Section: Study Rationalementioning

confidence: 99%

Environmental impacts of ancient copper mining and metallurgy: Multi-proxy investigation of human-landscape dynamics in the Faynan valley, southern Jordan

Knabb

Erel

Tirosh

et al. 2016

Journal of Archaeological Science

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a b s t r a c tThe environmental impact of mining and metallurgy is an issue that has affected societies in the ancient Near East over the past 8000 years. We present the results of a multidisciplinary project using agricultural sediments from ancient terraces as a cultural archive of environmental pollution and land use in the copper ore-rich Faynan valley of southern Jordan. Due to the simultaneous production of agricultural goods and copper metallurgy throughout the last 6000 years in the valley, environmental pollution and its consequences for human health have been considered as a factor in settlement abatement. Sediments from two farming terrace systems adjacent to the major mining and smelting locales were analyzed. The sediment analyses included metal concentrations, lead-isotopes and phytolith analysis, and OSL dating. Although measurable concentrations of lead and other heavy metals persist in ancient metallurgical waste piles, our investigations found minimal evidence for contamination in the adjacent terrace systems. Based on these results, we argue that the occurrence of environmental pollution in the Faynan valley is highly variable, and that the distribution of heavy metals resulted from a combination of natural and cultural factors, including persistent landscape features that helped contain the most polluted metallurgical deposits. These findings are significant for understanding the processes of landscape change and human impacts on desert environments, including the ways in which past human actions have negatively affected the environment, as well as preserved and protected the environment from further degradation.

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Greenland Ice Evidence of Hemispheric Lead Pollution Two Millennia Ago by Greek and Roman Civilizations

Cited by 661 publications

References 20 publications

(Pre-) historic changes in natural and anthropogenic heavy metals deposition inferred from two contrasting Swiss Alpine lakes

(Pre-) historic changes in natural and anthropogenic heavy metals deposition inferred from two contrasting Swiss Alpine lakes

Widespread pollution of the South American atmosphere predates the industrial revolution by 240 y

Environmental impacts of ancient copper mining and metallurgy: Multi-proxy investigation of human-landscape dynamics in the Faynan valley, southern Jordan

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