The Glacial Transport Theory posits that the bluestones (and potentially other megaliths) at Stonehenge were primarily moved from their Welsh origins to Salisbury Plain by glacial action during the Pleistocene, rather than through human effort, implying they were collected locally near Stonehenge as erratics rather than quarried, and/or collected, in Wales and transported.
Below is a comprehensive list of key evidence types that could prove or disprove this theory (or render it likely/unlikely), based on geological, archaeological, and glaciological principles. For each, we indicate whether it supports or refutes the theory, and annotate whether such evidence has been found, with details drawn from scientific analyses.
Evidence Table
Evidence Type | Supports or Refutes Theory | Has It Been Found? | Details and Sources |
---|---|---|---|
Presence of bluestone glacial erratics (boulders of matching lithology) scattered across Salisbury Plain, outside the immediate Stonehenge environs | Supports (would indicate widespread glacial deposition, allowing humans to collect them locally) | No | No bluestone erratics have been identified on Salisbury Plain beyond Stonehenge itself, despite extensive surveys; this absence contradicts expected glacial dispersal patterns [1, 2, 3, 4, 5, 6]. |
Evidence of glacial deposits, sediments, or landforms (e.g., moraines, till) on or near Salisbury Plain | Supports (would confirm ice sheets reached the area, enabling transport) | No | No glacigenic sediments, depositional landforms, or glacio-tectonic structures have been found on Salisbury Plain or adjacent areas east of north Somerset, inconsistent with glacial incursion. River gravels in nearby valleys (e.g., Wylye, Nadder, Avon) also lack glacially derived materials [5, 7, 6]. |
Glacial striations, faceting, or subglacial microwear on bluestones (e.g., scratches, gouges from ice pressure) | Supports (diagnostic of glacial modification during transport) | Disputed, but predominantly no | Some proponents claim faint striations on artefacts like the Newall Boulder indicate subglacial features, but recent petrographic, SEM-EDS, and XRF analyses show these are likely natural slickensides or fault-related, not glacial; no definitive glacial striations found on bluestones overall [5, 8, 9]. |
Geological or palaeoclimatic evidence that ice sheets extended to Salisbury Plain during relevant Pleistocene periods (e.g., Anglian or Wolstonian glaciations) | Supports (establishes feasibility of ice reaching the site) | No | Ice flow models and stratigraphy show glaciers did not extend east of the Somerset lowlands or south of the Vale of Moreton; topographic barriers (e.g., Mendips) and lack of evidence in southern England contradict this [13, 6]. |
An erratic dispersal train (trail of bluestone fragments) between Preseli Hills and Salisbury Plain | Supports (consistent with glacial dilution and deposition patterns) | No | No continuous train of erratics exists across southern England; dispersal fans (e.g., spotted dolerites) stop short and do not align with Stonehenge. Isolated finds (e.g., Gower coast boulder) are not on the direct path [14, 6]. |
Absence of Neolithic quarrying sites or extraction evidence in the Preseli Hills source areas | Supports (suggests stones were natural erratics, not human-quarried) | No | Quarries identified at Carn Goedog (spotted dolerite source) and Craig Rhos-y-felin (rhyolite source), with platforms, trackways, and tools indicating extraction [15, 16, 17, 18, 19]. |
Evidence of quarrying tools, methods, or debitage (waste flakes) at Welsh sites matching Stonehenge stones | Refutes (indicates human extraction and transport from origin) | Yes | Stone wedges, hammer stones, loading platforms, and in-situ tools found at quarries; Newall Boulder identified as rhyolite debitage from a broken monolith (e.g., Stone 32d), showing human shaping [20, 9, 19]. |
Dating of quarrying activity aligning with Stonehenge's construction phases (ca. 3000–2500 BC) | Refutes (links extraction to human timeline, not ancient glaciation) | Yes | Charcoal and platform dates from quarries yield ca. 3000 BC, matching Stonehenge's bluestone phase; chlorine-36 dating on a bluestone suggests exposure ca. 14,000 years BP, consistent with post-glacial human quarrying [15, 19, 6]. |
Geochemical and petrographic matching of Stonehenge bluestones to specific Welsh quarries (without glacial intermediaries) | Refutes (supports direct human sourcing from known sites) | Yes | Bluestones match Preseli outcrops (e.g., Carn Goedog for dolerite, Craig Rhos-y-felin for rhyolite); Newall Boulder provenance confirmed as Craig Rhos-y-felin via XRF and SEM-EDS [18, 21, 22, 9]. |
Evidence of human transport routes or capabilities (e.g., parallels in other Neolithic sites) | Refutes (demonstrates feasibility of human movement over 200+ km) | Yes | Archaeological parallels exist for long-distance megalith transport; proposed routes via Bristol Channel or overland, with evidence like Waun Mawn circle suggesting disassembly and relocation [23, 24, 19]. |
Conclusion
This evidence collectively makes the Glacial Transport Theory unlikely, as the preponderance (e.g., quarrying sites, absence of erratics/deposits) supports human transport. Proponents argue glaciers could move such boulders based on general capabilities, but lack site-specific proof. Recent studies have further refuted key claims, such as the Newall Boulder's glacial origin [9, 6].
References
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