Archaeology

Scientific archaeology at 伊人直播app is underpinned with excellent facilities in bioarchaeology, stable isotopes and geochemistry, archaeobotany, and material science. We have five dedicated research suites, comprising 23 preparation and analytical labs, as well as a range of analytical equipment both in our Wager Building and the nearby Chemical Analysis Facility (CAF). On this page you can find an overview of the facilities available for scientific archaeological research.

Bioarchaeology Suite

Bioarchaeology is the study of human skeletal remains and other biological materials - such as animal bones, insects and pollen - found on archaeological sites. We strive to understand all aspects of past human behaviour, including their health, diet and their living environment. We carry out detailed analysis of human and animal remains using macroscopic, microscopic, and chemical analyses within dedicated laboratory spaces, using a suite of advanced analytical equipment.

Archaeology research facilities at 伊人直播app

human osteoarchaeology and palaeopathology

In human bioarchaeology, we use digital, radiographic, thin-sectioning and microscopic imaging to explore aspects of health such as the nature and timing of fractures, underlying pathological processes, and the diagnosis of bone cancer. Our laboratories encompass digital X-ray facilities (Carestream, Faxitron), high-powered microscopy and thin-sectioning facilities. Our research reference collection includes a Clinical Radiograph Archive, extensive pathological examples, anatomical and osteological reference material, and measuring equipment.

We curate over 700 adult and non-adult skeletons from archaeological sites including: 19th century St John鈥檚 church, Redhill in Surrey; the multi-period site of St Oswald鈥檚 Priory, Gloucester, early medieval Bishopstone, Sussex and later medieval Hulton Abbey, Staffordshire.

Look at some recent research from this laboratory:

Key publications:

Lewis M. 2018. Palaeopathology of Children. Academic Press: London

Lewis M, Shapland F, and Watts R. 2016. On the threshold of adulthood: A new approach for the use of maturation indicators to assess puberty in adolescents from medieval England. American Journal of Human Biology 28(1):48-56.

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Zooarchaeology

In zooarchaeology, we examine animal bones for information on past husbandry regimes and the health of domesticated populations, hunting practices, diet, butchery technology and human impact on local and regional ecosystems. When combined with isotopic analysis, this can be used to shed light on fodder and animal diets, as well as questions relating to mobility and trade.

Our research reference archive comprises hundreds of wild and domestic mammal bones in addition to 45 bird and 60 fish species, many showing examples of taphonomic modifications and pathology. We also curate the early medieval faunal assemblage from Lyminge, Kent, one of the largest ever recovered from Anglo-Saxon England.

Look at some recent research from this laboratory:

Key publications:

Pluskowski A, Makowiecki D, Maltby M, Rannamäe E, Lõugas L, Maldre L, Daugnora L, Black S, Müldner G. and Seetah K, 2019. The Baltic Crusades and ecological transformation: The zooarchaeology of conquest and cultural change in the Eastern Baltic in the second millennium AD. Quaternary International, 510, pp.28-43.

Pluskowski A. 2019. Environment, Colonisation, and the Crusader States in Medieval Livonia and Prussia: Terra Sacra 1, Turnhout: Brepols.

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Stable Isotope and Geochemistry Suite

Sample preparation takes place in the Archaeology Department鈥檚 laboratories, with sample analysis carried out at 伊人直播app's state-of-the-art Chemical Analysis Facility (CAF). Archaeology researchers frequently use CAF facilities, for example NMR spectroscopy, mass spectrometry, X-Ray diffraction and scattering, optical spectroscopy, thermal analysis and electron microscopy. Many of these facilities are available to colleagues from across the university, offering scope for interdisciplinary collaboration.

stable isotope analysis

Our fully equipped sampling laboratory is used for preparing samples of bone, teeth and other biological materials for isotope analysis (i.e. carbon, nitrogen, oxygen, hydrogen) to reconstruct diet, mobility and ancient environments.

Our Geochemistry and Isotope Suite includes:

Sercon Elemental Analyser coupled to Europa 20-20 IRMS - for analysis of carbon and nitrogen in solid samples such as bone collagen and plants
ThermoFisher Scientific Delta V IRMS including a Conflo IV (TC/EA), and a GC-C interface - to measure both bulk and compound specific isotopes
ThermoFisher Scientific Delta Conflo IV with GasBench II - for carbonate carbon-oxygen analysis
Picarro L2120-I Isotopic Water Analyser -WS-CRDS - for analysis of hydrogen and oxygen in water.

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radiogenic isotope and trace element analysis

We have a fully-equipped clean laboratory to measure low-level trace elements and radiogenic isotopes (Pb) with applications in archaeology, forensic science and the food and beverage industry.

Our Thermo Scientific iCAP-Q Inductively Coupled Plasma Mass Spectrometer (ICP-MS) is fitted with an auto-sampler for analysis of radiogenic isotopes and low concentration trace element analyses. We have a Niton XL3t GOLDD+ Portable X-Ray Fluorescence Spectrometer (pXRF) for use in the laboratory and in the field for geochemical analyses. The School also maintains a Perkin Elmer Inductively Coupled Plasma Optical Emission Spectrometer (ICP-OES). Additional organic analysis instruments in CAF allow for the determination of lipids, peptides and a range of proteomics.

Look at some recent research from this laboratory:

Geochimica Et Cosmochimica Acta, 128: 13-28.

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Material Science

The Department has wide-ranging expertise on the analysis of ancient materials. We are developing new approaches to writing complex and biographies of objects and technologies. We use scientific analysis to give insight into dynamic processes in the past, such as changing social organisation and recycling economies. These involve the integrated application of several analytical instruments, new chemical and archaeological models, and world class excavation and on-campus museum archives.

Our facilities include a Microwave Plasma 鈥� Atomic Emission Spectrometer (MP-AES, Agilent Technologies) for high-quality analysis of ancient metal and glass (only the second device of its kind dedicated to archaeological materials in the UK), and with a Hydride Generation System (HG-MP-AES), we can deliver extremely low limits of detection (ppb) from small samples. We have three Portable X-Ray Fluorescence Spectrometers (pXRF) for use in the laboratory and in the field. These provide a flexible, quick and high-quality instrument for the rapid assessment of large assemblages and has recently been used in partnership with MOLA-Headland on their multi-period A14 infrastructure project. Our close links to the Chemical Analysis Facility (/caf/) provides a range of other key facilities including Thermo Scientific iCAP-Q Inductively Coupled Plasma Mass Spectrometer (ICP-MS), and FEI Quanta FEG 600 Environmental Scanning Electron Microscope (ESEM) with wavelength dispersive spectrometer. Overall, we combine field-leading chemical analysis with the Department鈥檚 other strengths in social and field archaeology, to deliver new insights into our material past.

Key Publications:

Bray PJ. 2020. Modelling Roman concepts of copper-alloy recycling and mutability: the chemical characterisation hypothesis and Roman Britain. In C. Duckworth and A. Wilson (eds.) Recycling and Reuse in the Roman Economy. Oxford, Oxford Studies on the Roman Economy.

Bray PJ. 2019. Chemistry and Bronze Age metals in Atlantic Europe: Flows of ideas and material. In B. Cunliffe and J. Koch (eds.) Exploring Celtic Origins, 117-153. Oxford: Oxbow

Bray PJ., Cu茅nod A, Gosden C, Hommel P, Liu R, Perucchetti L. and Pollard AM. 2015. Form and flow: The 鈥榢armic cycle鈥� of copper. Journal of Archaeological Science 56: 202-209.

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Geoarchaeology Suite

Geoarchaeology helps us to understand the sedimentary history of landscapes and sites, and the materials and technology used in buildings and artefacts, through the application of geological, soil and earth science techniques. It allows a deep-time perspective on interactions between humans and the environment, the sustainability of settlements and resource use, and living conditions and health.

Settlement histories can be unravelled by identifying activity areas and examining site formation processes and preservation conditions. We have expertise in high-resolution micromorphological analysis of undisturbed sequences of soils and settlement deposits and materials in large resin-impregnated thin-sections. This strengthens our understanding of their composition, deposition and preservation conditions.

sedimentology and micromorphology

Our sedimentology, micromorphology and materials analysis laboratories enable us to undertake in-depth high-resolution sediment description, soil micromorphology, particle size analysis, peat humification and organic matter determinations. With this information we can create deposit models (using Rockworks; ArcGIS). We can prepare soil micromorphology, geology and materials (e.g. pottery, stone, metal, shell, bone, pigment) thin-sections (small and large format up to 14 x 7 cm), including resin-impregnation, precision cutting, grinding and polishing (Logitech and Brot systems).

We have an extensive range of microscopy resources, including: optical, SEM EDX, infrared and Raman microscopy and spectroscopy, photomicrography, and image analysis (using Leica photomicrography and image analysis software). Our Leica optical microscopes enable analysis in plane, polarising, fluorescent, phase contrast, stereo-binocular, oblique-incident and reflected light. We have extensive reference collections of geological specimens, archive soil samples, and micromorphological thin-sections for researchers and comparative analysis.

We also carry out 3D reconstructions of artefacts and archaeological features such as those from our excavations at Silchester using Sketchfab and photogrammetry.

Look at some recent research from this laboratory:

Key publications

Banerjea, R. Y., García-Contreras Ruiz, G., Kalni艈š, G., Karczewski, M., Pluskowski, A., Valk, H. & Brown, A. D. 2021. , Landscapes 20(2): 178-201

Matthews, W. (2018) . In: Hodder, I. (ed.) Religion History and Place: The Origins of Settled Life. University of Colorado, Denver, pp. 107-39.

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Archaebotany Suite

We have dedicated laboratories for the extraction of macro- and microfossils from archaeological features (e.g. pits, ditches, hearths) and landscapes (e.g. bogs, lakes, caves).

Macrofossils provide key information on past economy and diet, as well as climate and environmental change, and the facilities permit extraction by flotation, wet sieving or dry sieving of charred and waterlogged plant remains, charcoal, insects, mollusca and animal bone.
Microfossils provide important information on past climate and environmental change, as well as land-use histories, and the facilities permit extraction of pollen grains and spores, non-pollen palynomorphs (fungal spores), diatoms, phytoliths, Cladocera and testate amoebae.

We have an extensive range of field equipment including peat corers, column, bulk and Kubiena sampling, all suitable for subsequent laboratory assessment and analysis. To retrieve deeply buried sediments and soils we use portable deep drilling equipment (Atlas Copco 2-stroke percussion engine and Eijkelkamp window/windowless sampler) for continuous quality core samples up to 15m in depth.

We have an extensive range of high-quality microscopes and modern and fossil reference specimen collections for the analysis of these remains, housed in three dedicated laboratories. The labs have computing and photographic facilities that permit image capture and analysis, and graphical representation and statistical analysis of data.

integrated archaebotany

Our wide range of facilities have enabled us to develop new Integrated Archaeobotanical approaches, as they permit recovery and in-situ analysis and identification of an exceptionally diverse range of plant remains and parts.

This integrated high-resolution micro-contextual approach is providing new insights into agricultural practices, diet, energy sources, built environments, waste-management and health. Major world-wide plant reference collections are also available in the School of Biological Sciences’ .

Read about our annual organised by Dr Rowena Banerjea, Dr Catherine Barnett, and Dr Lisa Lodwick (Oxford).

Key publications:

Banerjea R. Badura M., Kal膿js U. , Cerina A., Gos K., Hamilton-Dyer S., Maltby M., Seetah K. and Pluskowski A. 2017. A multi-proxy, diachronic and spatial perspective on the urban activities within an indigenous community in medieval Riga, Latvia. Quaternary International, 460: 3-21.

Branch N. and Marini N. 2014. Mid-Late Holocene environmental change and human activities in the northern Apennines, Italy. Quaternary International, 353: 34-51.

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Palaeoclimatology聽 Suite

Documenting past climate change and understanding how this has impacted humans is a fundamental part of our research at 伊人直播app, in collaboration with the departments of Geography, Environmental Science and Meteorology. Researchers come together at our Centre for Past Climate Change. Our contribution focuses on the last 11,700 years, with palaeoecological approaches being complemented by work such as data from the analysis of calcite deposited in stalactites in caves, or from shells and teeth in archaeological deposits, and through tree ring analysis in our dendrochronology laboratory.

carbonate analysis

We have a dedicated laboratory to drill calcite materials (e.g., stalagmites, shells and teeth) using a micro-mill (Sherline 5410), where samples can be collected at a resolution of 50 micrometres (0.050 mm). We have developed a preparation line and workflow for the extraction of stalagmite fluid inclusion water, which can then be analysed using our Picarro CRDS.

Learn about our Centre for Past Climate Change

Key publications:

Smith M., Singarayer J., Valdes P., Kaplan J. and Branch N. 2016. The biogeophysical climatic impacts of anthropogenic land use change during the Holocene. Climate of the Past, 12(4), pp.923-941.

Flohr P, Fleitmann D, Matthews R, Matthews W, and Black S. 2016. Evidence of resilience to past climate change in Southwest Asia: Early farming communities and the 9.2 and 8.2 ka events. Quaternary Science Reviews, 136, pp.23-39.

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Chemical Analysis Facility

The 伊人直播app's Chemical Analysis Facility supports our research in archaeology, chemistry, pharmacy, food biosciences, soil sciences and agriculture. Facilities include nuclear magnetic resonance, thermal analysis, molecular spectroscopy, X-ray diffraction and scattering, optical spectroscopy and mass spectrometry equipment and an electron microscopy laboratory. Access to the facility鈥檚 expertise and instruments is available to external collaborators as well as staff. .

Microwave Plasma - Atomic Emission Spectrometer (MP-AES)

The Department of Archaeology is just the second University to secure access to the MP-AES after securing funding from the Arts and Humanities Research Council (AHRC) and also funds allocated to the University from Research England.

The main function of the MP-AES is to produce very high quality chemical analysis, to improve the ability to understand ancient materials for example by analysing bronze, brass and other mixtures to a high degree of accuracy.

The machine uses microwaves to create nitrogen plasma, this heats up a liquid sample to several thousand degrees. At that temperature the sample gives out light at specific wavelengths depending on what elements were in the sample, detecting these can calculate the chemical composition.

As well as the potential to be involved in student projects the machine also provides the potential to undertake commercial work and do chemical surveys for archaeological units and other clients.

Quest

Quest (Quaternary Scientific) is a commercial enterprise within our School of Archaeology, Geography and Environmental Science (SAGES). It provides an expert Archaeological and Environmental Science service to archaeological units, environmental consultancies and government organisations. The specialist Quest team can manage pre-development investigation projects from initial set-up and design through to publication. The enterprise also has a network of specialist and technical staff that service all aspects of archaeological and environmental science contract work.

contact us

Professor Mary Lewis, Lead for Archaeological Science

m.e.lewis@reading.ac.uk

School of Archaeology, Geography and Environmental Science (SAGES)
伊人直播app
Wager Building
Whiteknights
伊人直播app
RG6 6AB
UK

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Archaeology Research Division

Department of Archaeology

Research Facilities at 伊人直播app

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Archaeological science facilities

human osteoarchaeology and palaeopathology

Zooarchaeology

stable isotope analysis

radiogenic isotope and trace element analysis

Material Science

sedimentology and micromorphology

integrated archaebotany

carbonate analysis

Microwave Plasma - Atomic Emission Spectrometer (MP-AES)

contact us

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