Research Projects in the Department of Archaeology

The ways Neanderthals treated their dead have been a key focus of long-standing debates about their capacities for compassion and symbolic thought, and their similarity to modern humans. These questions feed into broader questions concerning how similar Neanderthals were to ourselves, modern humans, especially in light of evidence that we interbred.

The above photo shows: A left lateral aspect of a cranium from Catignano (a Middle Neolithic village in Abruzzo), showing two healing trepanations on the left parietal bone and healed fracture on the left frontal and parietal bones of a 40-50 year old female

The project will develop an innovative new model to examine the pivotal role of anthropogenic wetlands in the long transition to agriculture in the Levant. Remarkably, while this transition has been explored in some detail, we still do not have a good grasp on the long-term developments and causes of the origins of agriculture, mainly due to a lack of direct botanical evidence.

The archaeology of Sub-Saharan Africa is rapidly gaining momentum, thanks to renewed efforts to decolonise and empower indigenous narratives of agency and creativity that have been bolstered further by the increasing application of scientific methods. However, important challenges remain. One is the scarcity of training and archaeological science capacity in sub-Saharan Africa, which is necessary to make these efforts sustainable.

Archaeological data is often biased and incomplete. This is a well-known issue for most archaeologists. Although studies of specific sites and small regions can have this into account, the effect of this problem increases exponentially as archaeologists expand their chronological and geographic frame, and try to answer questions related to general dynamics and broad human processes.

Analysis and evaluation of bronze axe hoards during the Late Bronze Age - Iron Age transition. The project investigates provenance, chronology, technological and cultural aspects of bronze deposition of the European Atlantic region.

The 10th-5th centuries BCE (the first centuries of the Iron Age) witnessed significant societal transformations across the Mediterranean. Populations grew in many regions, the first genuine economic integration of the basin occurred through maritime interaction and overseas settlement, and, for the first time, communities characterisable as urban and state-like are identifiable from the sea’s eastern littoral (where they had a deeper Bronze Age history) through to its Atlantic border.

‘BODIES MATTER’ focuses on the material culture of bodies (and the self) in colonial borderlands by comparing three frontiers at various periods and geographies: the Spanish Empire’s southern borderland in the Americas in the AD 16th-19th century, the Punic western Mediterranean in the 6th-2nd century BC, and the Islamic-Christian Ethiopian frontier between the AD 10th and 15th century.

The Late Bronze Age (LBA) and Early Iron Age (EIA) in southwest Asia saw major socio-political transformations, including the rise and fall of the Hittite, Kassite and Neo-Assyrian empires. Alongside socio-political and economic instability, climatically induced droughts are among the most frequently cited causes for the collapse of these states. However, direct evidence for the impact of droughts on agricultural systems is virtually absent from these periods, rendering hypotheses that see climate change at the heart of the crises hypothetical.

This project is documenting the knowledge, skills, and practices of traditional dry-stone masonry at Great Zimbabwe, southern Zimbabwe. Once the capital of an Iron Age empire, Great Zimbabwe is an ancient settlement complex with dry-stone structures covering over 720 hectares. Around it, local communities live and maintain ancestral connections to the site. The most outstanding material remains are stone structures, built without use of mortar or any binding material.

EHSCAN is a Horizon-MSCA-2022-PF scheme Fellowship Funded by UKRI and hosted by the McDonald Institute for Archaeological Research, University of Cambridge. 

Tracking the early emergence of derived Homo-like cerebral features in the hominin fossil record can be expected to contribute to an understanding of the timing (i.e., chronology) and mode (i.e., process) of critical brain changes. Because brain tissue is not preserved in the fossil record, studies of hominin brain evolution focus on brain endocasts (i.e., replicas of the inner table of the bony braincase).

Our knowledge of human evolution is limited by several factors. One is tightly linked to the nature of the fossil record, as bones of our extinct human relatives and other primate species rarely appear in archaeological and paleontological sites, and when they do, they very commonly appear in an isolated fashion and/or are highly fragmented. These factors more severely affect studies of limb bones, which have been vaguely analysed or even ignored in certain cases.

This archaeology-led initiative focuses on the East Anglian Fens, an extraordinary landscape where exceptional preservation of organic artefacts and environmental evidence gives unparalleled insights into the last 5,000 years of communities, resources and habitats.

The last decades have witnessed marked achievements of STEM in understanding the remains of humans, animals, and plants from the past by analyzing different materials, both inorganic and organic. These developments have opened-up the great potential for increasing our understanding of cultural heritage, and hence for developing better strategies for its protection and management.

How did our ancestors walk? Perhaps the greatest challenge that this question has posed in the past, is the lack of methodological applications in which no study has previously reconstructed how our ancestors moved using biomechanical modelling techniques. We need to consider not just individual bones when reconstructing movement, but to look at the full body to begin to tell the story of our ancestors’ movement. Muscles animate our body, permitting us to walk, run and even dance. We must reconstruct the muscles of the body to understand ancestral locomotion.

A large-scale multi-disciplinary study of pre-Roman iron technology in the Iberian Peninsula.

Despite recent progress in molecular analyses and the constant increase of the hominin remains in the fossil record, the chronological, geographical and evolutionary context of the emergence of the genus Homo remains largely debated. More importantly, the identity of our direct ancestors and assessment of the adaptations characterizing our genus remain unclear.