Summary
For over 3 million years, stone tools were central to the survival of hominins (fossil and modern humans). Their ability to cut, pierce and scrape materials opened new ecological niches, facilitated exploitation of novel resources, and allowed hominins to survive in hostile environments. Accordingly, there were strong pressures for stone tools to be effective, reliable, durable, and efficient. Modern cutting tools are produced according to similar principles and there is >80 years of research dedicated to designing mechanically-optimised tools and understanding the principles of cutting. However, Palaeolithic stone technologies have yet to be investigated with similar mechanical or theoretical rigour.
EDGE will integrate advanced engineering analytical techniques, principles and design theory with large-scale archaeological experiments to investigate how the morphology, microgeometry, and raw material choice of stone cutting tools influences their performance and fracture mechanics. In archaeological firsts, EDGE includes controlled cutting tests, empirical analyses of stone tool sharpness, and finite element analysis (FEA) of cutting processes. Palaeolithic artefacts will be examined to assess whether our hominin ancestors actually designed mechanically-optimised tools, or, alternatively, whether other factors (e.g. cultural variation) underlie the tool type, form and raw material variability observed across the Palaeolithic archaeological record.
The ground breaking nature of EDGE is its integration of advanced engineering techniques and principles with archaeological experiments and artefact analyses to address fundamental questions concerning early human behaviour. Results will provide a fundamental shift in how functional archaeological experiments are performed, establish fracture mechanics theory and FEA within archaeological research, and present a robust mechanically defined framework necessary for understanding artefact variation across the Palaeolithic.
EDGE will integrate advanced engineering analytical techniques, principles and design theory with large-scale archaeological experiments to investigate how the morphology, microgeometry, and raw material choice of stone cutting tools influences their performance and fracture mechanics. In archaeological firsts, EDGE includes controlled cutting tests, empirical analyses of stone tool sharpness, and finite element analysis (FEA) of cutting processes. Palaeolithic artefacts will be examined to assess whether our hominin ancestors actually designed mechanically-optimised tools, or, alternatively, whether other factors (e.g. cultural variation) underlie the tool type, form and raw material variability observed across the Palaeolithic archaeological record.
The ground breaking nature of EDGE is its integration of advanced engineering techniques and principles with archaeological experiments and artefact analyses to address fundamental questions concerning early human behaviour. Results will provide a fundamental shift in how functional archaeological experiments are performed, establish fracture mechanics theory and FEA within archaeological research, and present a robust mechanically defined framework necessary for understanding artefact variation across the Palaeolithic.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/843760 |
| Start date: | 01-09-2021 |
| End date: | 31-08-2024 |
| Total budget - Public funding: | 253 052,16 Euro - 253 052,00 Euro |
Cordis data
Original description
For over 3 million years, stone tools were central to the survival of hominins (fossil and modern humans). Their ability to cut, pierce and scrape materials opened new ecological niches, facilitated exploitation of novel resources, and allowed hominins to survive in hostile environments. Accordingly, there were strong pressures for stone tools to be effective, reliable, durable, and efficient. Modern cutting tools are produced according to similar principles and there is >80 years of research dedicated to designing mechanically-optimised tools and understanding the principles of cutting. However, Palaeolithic stone technologies have yet to be investigated with similar mechanical or theoretical rigour.EDGE will integrate advanced engineering analytical techniques, principles and design theory with large-scale archaeological experiments to investigate how the morphology, microgeometry, and raw material choice of stone cutting tools influences their performance and fracture mechanics. In archaeological firsts, EDGE includes controlled cutting tests, empirical analyses of stone tool sharpness, and finite element analysis (FEA) of cutting processes. Palaeolithic artefacts will be examined to assess whether our hominin ancestors actually designed mechanically-optimised tools, or, alternatively, whether other factors (e.g. cultural variation) underlie the tool type, form and raw material variability observed across the Palaeolithic archaeological record.
The ground breaking nature of EDGE is its integration of advanced engineering techniques and principles with archaeological experiments and artefact analyses to address fundamental questions concerning early human behaviour. Results will provide a fundamental shift in how functional archaeological experiments are performed, establish fracture mechanics theory and FEA within archaeological research, and present a robust mechanically defined framework necessary for understanding artefact variation across the Palaeolithic.
Status
CLOSEDCall topic
MSCA-IF-2018Update Date
28-04-2024
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