MMI partial extraction geochemistry for the resolution of anthropogenic activities across the archaeological Roman town of Calleva Atrebatum

Sylvester, G.C.; Mann, A.; Cook, Samantha R.; Wilson, Clare

doi:10.1144/geochem2017-009

Cited by 3 publications

(4 citation statements)

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“…In this regard, the successful experience of adapting geochemical prosepcting methods of buried ('blind') ore bodies and deposits (better known as Mobile Metal Ion geochemistry [MMI]) for archaeological sites may become a reliable tool for selecting the direction of archaeological priority activities and the sites will be subjected to excavation (cf. Sylvester et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Geochemical-archaeological research started as early as the first decades of the 20th century (e.g., Arrhenius, 1931;1934;Rimmington, 2000). Recently, more targeted and methodical works have been carried out in this direction in some countries (Bethell & Smith, 1989;Booth et al, 2017;Cook et al, 2005;Pringle et al, 2022;Stijn Oonk et al, 2012;Sylvester et al, 2017), and in this context, the research conducted on the Artanish Peninsula seems to open new perspectives (Figure 1). This is especially true in the sense that so far the parameters of geochemical anomalies formed around and above (in the soil of) archaeological sites have only been used to determine the general geochemical description of archaeological sites.…”

Section: Introductionmentioning

confidence: 99%

“…Geochemical‐archaeological research started as early as the first decades of the 20th century (e.g., Arrhenius, 1931; 1934; Rimmington, 2000). Recently, more targeted and methodical works have been carried out in this direction in some countries (Bethell & Smith, 1989; Booth et al, 2017; Cook et al, 2005; Pringle et al, 2022; Stijn Oonk et al, 2012; Sylvester et al, 2017), and in this context, the research conducted on the Artanish Peninsula seems to open new perspectives (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Geoarchaeological investigations in Artanish Peninsula, Armenia: Testing a new geochemical prospecting method for archaeology

Hovhannisyan,

Bobokhyan,

Kunze

et al. 2023

Archaeological Prospection

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Within the framework of an Armenian–German research project, taking place between 2019 and 2021 on the Artanish Peninsula at Lake Sevan (Armenia), in addition to numerous (geo‐) archaeological investigations, methods of geochemical prospection have been carried out. The ancient burial grounds of Artanish 23 and Artanish 29 have served as model sites to successfully test the well‐known method of geochemical prospection and evaluation of metal deposits in geology (mineral sector). As a result, a new experimental archaeo‐geochemical prospecting and evaluation method has been developed, which has been adapted for the exploration of archaeological monuments. It is planned to use this experimental method (which we consider new and important in archaeogeochemical investigation, but not a conclusive and comprehensive work per se), which has already proven its work capacity, in archaeological research, in the prospective areas of Armenia and other countries. In addition to these investigations, research on the transformations in the landscape of the ancient tombs related to Lake Sevan fluctuations has also been carried out. The anthropogenic impact of humans on the environment (geochemical halos formed in the soil on the surface of the tombs) has been studied, as well as the problem of the impact of geological environment on human life activities, that is, the relocation of the burial grounds to more elevated areas due to the rise in the lake level. Based on the results of geochemical sampling and high‐resolution magnetometer surveys, excavations have been performed at the site. Here, we present the results of an experimental study exploring the potential of combined magnetometer prospection and chemical soil analyses to locate and characterize the burial ground of Artanish on Lake Sevan, Armenia. The results have demonstrated the capability of these analyses to detect the sites, outline hotspots and interpret the features identified in the magnetometer results.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Geoarchaeological investigations in Artanish Peninsula, Armenia: Testing a new geochemical prospecting method for archaeology

Hovhannisyan,

Bobokhyan,

Kunze

et al. 2023

Archaeological Prospection

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“…mapping, digital soil mapping, resource evaluation, geochemical exploration, and forensic geochemistry (e.g. McBratney et al 2003;Welte & von Eynatten 2004;Keegan et al 2008;Feng et al 2011;Bowen & Caven 2013;Frei & Frei 2013;Reid et al 2013;Zhang et al 2014b;Mann et al 2015Mann et al , 2016Blake et al 2016;Sylvester et al 2017). Mann et al (2016) used the multi-element Mobile Metal Ion® (MMI - Mann et al 1998;Mann 2010) dataset from the National Geochemical Survey of Australia (Caritat & Cooper 2011a) to develop the concept of degree of geochemical similarity (DOGS).…”

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An improved method for assessing the degree of geochemical similarity (DOGS2) between samples from multi-element geochemical datasets

Caritat

Mann

2018

GEEA

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The multi-element aqua regia National Geochemical Survey of Australia (NGSA) database is used to demonstrate an improved method for quantifying the degree of geochemical similarity (DOGS2) between soil samples. The improvements introduced here address issues relating to compositional data (closure, relative scale). After removing the elements with excessive censored (below detection) values, the rank-based Spearman correlation coefficient (r s ) between samples is calculated for the remaining 51 elements. Each element is given equal weight through the rank-based correlation. The r s values for pairs of samples of known similar origin (e.g. granitoid-derived) are significantly positive, whereas they are significantly negative for pairs of samples of known dissimilar origin (e.g. granitoid-v. greenstone-derived). Maps of r s for all samples in the database against various reference samples are used to obtain correlation maps for lithological derivations. Likewise, the distribution of soils having a geochemical fingerprint similar to established mineralized provinces can be mapped, providing a simple, first order mineral prospectivity tool. Sensitivity of results to the removal of up to a dozen elements from the correlation indicates the method to be extremely robust. The new method is compliant with contemporary compositional data analysis principles and is applicable to various digestion methods.Multi-element databases, often containing in excess of 50 elements, are a common product of modern soil geochemistry programs, primarily due to the quality and quantity of data produced by modern instrumentation, in particular inductively coupled plasmamass spectrometry (ICP-MS). Presentation of informative statistical analysis derived from such datasets can be challenging and is commonly limited to one or two elements of interest, either because they are sought-after commodities or pathfinders in an exploration program or are potential contaminants in an environmental impact assessment. The alternative approach is to consider a geochemical composition as a multi-dimensional 'whole' and treat the data in a multivariate way. Correlation analysis can thus be used to define elements with common geochemical behaviour. Recently, principal component analysis (PCA) has been used to objectively 'discover' suites of elements with common characteristics (e.g. Caritat & Grunsky 2013; Zhang et al. 2014a), which can then guide follow-up interpretation. Grunsky (2010) provided a comprehensive discussion of multivariate data analysis techniques, including PCA and cluster analysis methods. The systematic and objective examination of databases for pattern recognition or inference of lithology and geology commonly requires advanced statistical and/or coding skills. The widely varying concentrations of elements in a multielement compositional database and their interdependencies present special problems for statistics-based methods of analysis (Aitchison 1986).Determining quantitatively how geological samples are similar or not based on majo...

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Formation and Properties of Urban Soils

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2022

Urban Soils

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MMI partial extraction geochemistry for the resolution of anthropogenic activities across the archaeological Roman town of Calleva Atrebatum

Cited by 3 publications

References 26 publications

Geoarchaeological investigations in Artanish Peninsula, Armenia: Testing a new geochemical prospecting method for archaeology

Geoarchaeological investigations in Artanish Peninsula, Armenia: Testing a new geochemical prospecting method for archaeology

An improved method for assessing the degree of geochemical similarity (DOGS2) between samples from multi-element geochemical datasets

Formation and Properties of Urban Soils

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