Gebruiker:Thor NL/Onderhanden werk/Archeoastronomie en Stonehenge

The prehistoric monument of Stonehenge has long been studied for its possible connections with ancient astronomy. Archaeoastronomers have claimed that Stonehenge represents an "ancient observatory," although the extent of its use for that purpose is in dispute.

The recent discovery of a neighbour to the Heel Stone has challenged the interpretation of it as a midsummer sunrise marker and the second stone may have instead been one side of a 'solar corridor' used to frame the sunrise. Sun worship is certainly not an uncommon phenomenon amongst Neolithic peoples given their reliance on it for crop fertility

Early work[bewerken | brontekst bewerken]

Stonehenge is aligned north east — south west, and it has been suggested that particular significance was placed by its builders on the solstice and equinox points, so for example on a midsummer's morning, the sun rose close to the Heel Stone, and the sun's first rays went directly into the centre of the monument between the horseshoe arrangement. Midwinter sunset would also occur at this point. It is unlikely that such an alignment can have been merely accidental. This astronomical function had been acknowledged since William Stukeley drew the site and first identified its axis along the midsummer sunrise in 1740.

Even Stukeley himself had noticed that the Heel Stone was not precisely aligned on the sunrise however but later archaeologists such as William Flinders Petrie considered that the site was dedicated to the worship of the sun. Year to year, the movement of the sun across the sky appears regular but the cycle of precession created by the wobble in the earth's rotation and in fact the Heel Stone would have been even further off the line of the sunrise four or five thousand years ago.

Early efforts to date Stonehenge exploited tiny changes in astronomical alignments and led to efforts such as H Broome's 1864 theory that the monument was built in 977 BC as that was when the star Sirius would have risen over Stonehenge's Avenue. Sir Norman Lockyer conjured a date of 1680 BC based entirely on an incorrect sunrise azimuth for the Avenue, aligning it on a nearby Ordnance Survey trig point, a modern feature. Petrie preferred a later date of AD 730 although the necessary stones were leaning considerably during his survey and it was not considered credible. Criticism of Lockyer and Petrie's methods led to an abeyance in archaeoastronomy at the site until the later twentieth century.

A huge debate was triggered by the 1963 publication of Stonehenge Decoded, by British born astronomer Gerald Hawkins, who claimed to see a large number of alignments, both lunar and solar, and argued that Stonehenge could have been used to predict eclipses. Hawkins' book received wide publicity, partly because he used a computer in his calculations, then a rarity. Archaeologists were suspicious in the face of further contributions to the debate coming from British astronomer C. A. 'Peter' Newham and Sir Fred Hoyle, the famous Cambridge Cosmologist, as well as by Alexander Thom, a retired professor of engineering, who had been studying stone circles for more than 20 years. Their theories have faced criticism in recent decades from Richard Atkinson and others who have suggested impracticalities in the 'Stone Age calculator' interpretative approach.

Newham and the Station Stones[bewerken | brontekst bewerken]

Newham had found an alignment for the equinonxes by drawing a line between one of the Station Stones with a posthole next to the Heel Stone. Moving away from the sun, he also identified a lunar alignment; the long sides of the rectangle created by the four station stones matched the moon rise and moonset at the major standstill.

Two of the Station Stones are damaged and although their positions would create an approximate rectangle, their date and thus their relationship with the other features at the site is uncertain. Stonehenge's latitude is unusual in that only at this approximate latitude (within about 50 km) do the lunar and solar events above occur at right angles to one another. More than 50 km North or South of the latitude of Stonehenge, the station stones would have to be set out as a parallelogram.

Hawkins' work[bewerken | brontekst bewerken]

Gerald Hawkins' work on Stonehenge was first published in Nature in 1963 following analysis he had carried out using the Harvard-Smithsonian IBM computer. Hawkins found not one or two alignments but dozens. He had studied 165 significant features at the monument and used the computer to check every alignment between them against every rising and setting point for the sun , moon, planets and bright stars in the positions they would have been in 1500 BC. 13 solar and 11 lunar correlations were very precise against the early features at the site with precision falling during the megalithic stages. He also calculated a method for using the Aubrey holes to predict lunar eclipses by moving markers from hole to hole. In 1965 Hawkins wrote (with JB White) Stonehenge Decoded which detailed his findings and proposed the monument to have been a 'Neolithic computer'.

Atkinson replied with his article Moonshine on Stonehenge in Antiquity in 1966 pointing out that some of the pits Hawkins had used for his sight lines were more likely to have been natural depressions and that he had allowed a margin of error of up to 2 degrees in his alignments. Atkinson found that the likelihood of so many alignments being visible from 165 points to be close to evens rather that the 'one in a million' possibility that Hawkins had claimed. That the Station Stones stood on top of the earlier Aubrey Holes meant that any of Hawkin's alignments between the two features were illusory.

Further criticisms of the Aubrey Holes' interpretation as astronomical markers, including Fred Holye's work, are contained in that article.

A question also exists over whether the English climate would have permitted accurate observation of astronomical events. The modern researchers were looking for alignments with phenomena they already new existed, the prehistoric users of the site did not have this advantage.

Thom's work[bewerken | brontekst bewerken]

Alexander Thom had been examining stone circles since the 1950s in search of astronomical alignments and the megalithic yard but it was not until 1973 that he turned his attention to Stonehenge. Thom chose to ignore alignments between features within the monument, considering them to be too close together to be reliable and instead looked for landscape features that could have marked lunar and solar events. One of Thom's key sites, Peter's Mound turned out to be a twentieth century rubbish dump however and time has not been kind to his approach.

Later theories[bewerken | brontekst bewerken]

John North

Despite as many as 20,000 people visiting Stonehenge during the 2005 summer solstice, growing evidence indicates that ancestors did not visit at all in the summer, but rather during the winter solstice. The only megalithic monument in the British Isles to contain a clear, compelling solar alignment is Newgrange which famously faces the winter solstice sunrise. The most recent such evidence includes bones and teeth from pigs that were slaughtered at nearby Durrington Walls, their age at death indicating that they were slaughtered either in December or January every year. Mike Parker Pearson of the University of Sheffield has said "We have no evidence that anyone was in the landscape in summer." ^[1]

Today, the consensus is that some of the astronomical case, although not all, was overstated.

Reference[bewerken | brontekst bewerken]

• Chippendale, C "Stonehenge Complete" (Thames and Hudson, London, 2004)

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