13 research outputs found
Linking forest cover, soil erosion and mire hydrology to late-Holocene human activity and climate in NW Spain
This article is distributed under the terms of the Creative Commons Attribution-NonCommercial 3.0 License (http://www.creativecommons.org/licenses/by-nc/3.0/) which permits non-commercial use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access page (http://www.uk.sagepub.com/aboutus/openaccess.htm).This article has been made available through the Brunel Open Access Publishing Fund.Forest clearance is one of the main drivers of soil erosion and hydrological changes in mires, although climate may also play a significant role. Because of the wide range of factors involved, understanding these complex links requires long-term multi-proxy approaches and research on the best proxies to focus. A peat core from NW Spain (Cruz do Bocelo mire), spanning the last ~3000 years, has been studied at high resolution by physical (density and loss on ignition (LOI)), geochemical (elemental composition) and palynological (pollen and non-pollen palynomorphs) analyses. Proxies related to mineral matter fluxes from the catchment (lithogenic tracers, Glomus and Entorrhiza), rainfall (Bromine), mire hydrology (HdV-18), human pressure (Cerealia-type, nitrophilous taxa and coprophilous fungi) and forest cover (mesophilous tree taxa) were the most useful to reconstruct the evolution of the mire and its catchment. Forest clearance for farming was one of the main drivers of environmental change from at least the local Iron Age (~2685 cal. yr BP) onwards. The most intense phase of deforestation occurred during Roman and Germanic times and the late Middle Ages. During these phases, the entire catchment was affected, resulting in enhanced soil erosion and severe hydrological modifications of the mire. Climate, especially rainfall, may have also accelerated these processes during wetter periods. However, it is noteworthy that the hydrology of the mire seems to have been insensitive to rainfall variations when mesophilous forest dominated. Abrupt changes were only detected once intense forest clearance commenced during the Iron Age/Roman transition (~2190 cal. yr BP) phase, which represented a tipping point in catchment's ability to buffer impacts. Overall, our findings highlight the importance of studying ecosystems' long-term trajectories and catchment-wide processes when implementing mire habitat protection measures.This work was funded by the projects CGL2010-20672 (Plan Nacional I+D+i, Spanish Ministry of Science and Innovation) and 10PXIB200182PR (General Directorate of I+D, Xunta de Galicia). N Silva-Sánchez and L López-Merino are currently supported by a FPU predoctoral scholarship (AP2010-3264) funded by the Spanish Government and a MINT postdoctoral fellowship funded by the Brunel Institute for the Environment,
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Recent anthropogenic impact in ancient Lake Ohrid (Macedonia/Albania): a palaeolimnological approach
Identifying evidence for past mining and metallurgy from a record of metal contamination preserved in an ombrotrophic mire near Leadhills, SW Scotland, UK
This study presents a new 3600-year record of past metal contamination from a bog located close to the Leadhills and Wanlockhead orefield of southwest Scotland. A peat core, collected from Toddle Moss, was radiocarbon (14C) dated and analysed for trace metal concentrations (by EMMA) and lead isotopes (by ICP-MS) to reconstruct the atmospheric deposition history of trace metal contamination, in particular, lead. The results show good agreement with documented historical and archaeological records of mining and metallurgy in the region: the peak in metal mining during the 18th century, the decline of lead mining during the Anglo-Scottish war and lead smelting during the early medieval period. There may also have been earlier workings during the Late Bronze and Iron Ages indicated by slight increases in lead concentrations, the Pb/Ti ratio and a shift in 206Pb/207Pb ratios, which compare favourably to the signatures of a galena ore from Leadhills and Wanlockhead. In contrast to other records across Europe, no sizeable lead enrichment was recorded during the Roman Iron Age, suggesting that the orefield was not a significant part of the Roman lead extraction industry in Britain. These findings add to the various strands of archaeological evidence that hint at an early lead extraction and metallurgical industry based in southern Scotland. The results also provide further evidence for specific regional variations in the evolution of mining and metallurgy and an associated contamination signal during prehistoric and Roman times across Europe
Major and trace elements in soils in the Central Pyrenees: high altitude soils as a cumulative record of background atmospheric contamination over SW Europe
16 páginas,5 tablas, 5 figuras.Background, aim, and scope High mountain soils constitute a long-term cumulative record of atmospherically
deposited trace elements from both natural and anthropogenic sources. The main aims of this study were to
determine the level of major and trace metals (Al, Ti,
Mn, Fe, and Zr) of lithologic origin and airborne
contaminating trace elements (Ni, Cu, Zn, As, Cd, and
Pb) in soils in the Central Pyrenees as an indication of
background contamination over SW Europe, to establish
whether there is a spatial pattern of accumulation of
trace elements in soils as a function of altitude, and to
examine whether altitude-related physicochemical properties of soils affect the accumulation of major metals
and trace elements.
Methods Major metals and trace elements were measured in
“top” (i.e., first 10 cm) and “bottom” (i.e., below 10 cm) soil
samples along an altitudinal transect (1,520-2,880 m a.s.l.) in
the Central Pyrenees. Total concentrations were determined
by X-ray fluorescense spectrometry. Total major metal
concentrations were analysed by conventional X-ray fluorescence spectrometry (XRF) with a Siemens SRS 303
instrument. Total trace element concentrations were determined with an energy-dispersive multielement miniprobe
XRF analyser. Acid-extractable concentrations were measured by inductively coupled plasma after previous extraction with nitric acid and hydrogen peroxide in closed
beakers. Acid-extractable major metal concentrations were
measured by inductively coupled plasma (ICP)-Optic Emission Spectrometry with a Perkin Elmer 3200 RL Instrument.
Acid-extractable trace element concentrations were determined by ICP-Mass Spectrometry with a Perkin Elmer
ELAN 6000.
Results Trace element concentration ranges were (in
mg kg
−1
, inventories in g m
−2
between parenthesis) <2-58
(0.5-6.6) for Ni, 6-30 (0.2-3.4) for Cu, 38-236 (1.6-32.4)
for Zn, 6-209 (0.2-12.8) for As, 0.02-0.64 (<0.04) for Cd,
and 28-94 (0.6-13.0) for Pb. These concentrations were, in
general, comparable to those recorded in soils from other
European mountainous areas and were in many cases above
the threshold recommended for ecosystem protection by
regional and European environmental authorities. The
highest concentrations were found at lower altitudes,
indicating an effect of local contamination up to
∼2,300 m a.s.l. Only above this altitude can trace elements
in soils be considered representative of a background, longrange atmospheric contamination.
Conclusions None of the storage capacity properties of
soils examined were determinant of the differences in
elemental concentrations along the altitudinal transect. At
the upper altitude range, Ni, Cu, and Pb showed a
approximately two- to fivefold increase over the average
concentration of the local dominant lithology, reflecting the
regional and global background of atmospheric contamination in the area.This work was part of the EU funded EUROLIMPACS project (GOCE-CT-2003-505540) and the GRACCIE
(CSD2007-00067) project, funded by the Spanish Ministry of
Science. M. Bacardit received financial support from the Spanish
Council for Scientific Research (CSIC) through an I3P pre-doctoral
grant.Peer reviewe