During its first half-century of existence, archaeoastronomy has ma-tured considerably as a discipline, moving on from “alignment hunting” to addressing culturally relevant questions. In the same period, Casa Rinconada has been transformed from a building containing numerous potential solar and lunar alignments (an idea that never really resonated with the cultural evidence) to a central point within an astronomically referenced sacred landscape.

See also:

Archaeoastronomy; Cardinal Directions; Pilgrimage. Chaco Canyon; Chaco Meridian; Fajada Butte Sun Dagger; Navajo Hogan; Pawnee Earth Lodge; Stonehenge.

References and further reading

Aveni, Anthony F., ed. Archaeoastronomy in the New World, 205–219. Cambridge: Cambridge University Press, 1982. ———. World Archaeoastronomy, 153–154, 365–376. Cambridge: Cambridge University Press, 1989. Krupp, Edwin C. Echoes of the Ancient Skies, 231–236. Oxford: Oxford University Press, 1983. Lekson, Stephen H. The Chaco Meridian: Centers of Political Power in the Ancient Southwest, 82–86. Walnut Creek, CA: AltaMira Press, 1999. Noble, David G., ed. New Light on Chaco Canyon, 69–70. Santa Fe: School of American Research Press, 1984. Redman, Charles, ed. Social Archaeology: Beyond Substance and Dating, 37–59. New York: Academic Press, 1978.

Catastrophic Events

Unexpected events in past skies, such as eclipses or the appearance of comets and meteors, could cause fear and even social disruption. In particular, they could threaten the power of elites, which was often predicated on being able to control the celestial bodies and keep them regular and predictable.

It has been suggested by some astronomers that cometary activity might have been much greater at certain epochs in the past, resulting in periods when sightings of spectacular comets and meteors were much more common. One such period occurred during the second millennium B.C.E., causing considerably more “active” skies, and the unrest that these caused brought about significant social and political upheaval, together with abrupt changes in beliefs systems in many parts of the world. The astronomical arguments remain controversial, but even if one accepts them, there are problems on the archaeological side. For sure, major social and ideological changes affected many human societies all round the globe during the second millennium B.C.E., but one has to question whether this period was much different from any other era in the last few millennia in this respect. In any case, the impact of fearsome sights in the sky on any particular group of people would have depended greatly upon all the other, more

The Barringer Meteor Crater near Winslow, Arizona. By chance, the camera has caught a meteor in the sky above the crater. (Bryan Allen/Corbis)

localized problems that were of concern at the time. The sky was important, but it wasn’t everything.

Since the 1990s, increased cometary activity in the past has engendered a great deal of interest, but largely for another reason: the increased probability of physical impacts from small meteorites hitting the earth. Though derived from the same astronomical cause, this is a fundamentally different issue in human terms. Meteoritic impacts have a direct physical outcome. Even a small meteoritic impact can have a devastating short-term effect on the climate, causing atmospheric dust, which leads to growth-free “cold summers” over vast areas.

And such effects did happen, which is clearly shown by evidence from dendrochronology (tree-ring dating). This dating technique is capable of assigning individual growth rings in particular timbers to a particular year. As a result, we know that during certain years in the last five millennia, there was virtually no significant tree growth anywhere in the northern hemisphere. The years with the most severe climatic downturns were 2345 B.C.E., 1628 B.C.E., 1159 B.C.E., and 536 C.E. When these events were first identified in the tree-ring record, the cause was suspected to be volcanic eruptions, but the Northern Irish dendrochronologist Mike Baillie has argued strongly against this. If one accepts that the cause of some or all of the climatic downturns was indeed a meteoritic impact, this does not mean such impacts were more likely in the past; on the contrary, they may be as likely today as ever.

Whatever did cause these climatic downturns, questions about their impact on the Earth’s population at the time can only be addressed by carefully piecing together fragments of archaeological, historical, and environmental evidence. In the meantime, the popular wave of interest in meteoritic impacts that ensued in the late 1990s generated everything from theories of global catastrophe and revolutionary social change throughout the world in the mid-sixth century C.E. to totally unsustainable ideas that Stonehenge in England was built to observe and predict meteoritic impacts.

See also:

Comets, Novae, and Meteors; Lunar Eclipses; Power; Solar Eclipses. Stonehenge.

References and further reading

Bailey, Mark. “Recent Results in Cometary Astronomy: Implications for the Ancient Sky.” Vistas in Astronomy 39 (1995), 647–671. Bailey, Mark, Victor Clube, and Bill Napier. The Origin of Comets. London: Pergamon Press, 1990. Baillie, Mike. From Exodus to Arthur: Catastrophic Encounters with

Comets. London: Batsford, 1999. Keys, David. Catastrophe. London: Century Books, 1999. Peiser, Benny, Trevor Palmer, and Mark Bailey, eds. Natural Catastrophes

during Bronze Age Civilisations: Archaeological, Geological, Astronomical and Cultural Perspectives. Oxford: Archaeopress (BAR International Series 728), 1998.

Steel, Duncan. Rogue Asteroids and Doomsday Comets: The Search for the Million Megaton Menace That Threatens Life on Earth. Chichester: Wiley, 1995.

Celestial Poles

See Celestial Sphere.

Celestial Sphere

The earth is surrounded by stars at various distances, but when the night sky is viewed on a clear night from anywhere on the earth, it appears that all the stars (and other celestial objects) are fixed onto a huge sphere surrounding the observer. From any given place at any given time, roughly half of the sphere is visible above the horizon, provided that there are clear views unobscured by things like trees or buildings. The other half is below the horizon and invisible.

The earth rotates in space once a day, and the stars are effectively motionless. (They are actually in motion with respect to one another, but generally the effects of these proper motions are so negligible that they will not affect the configurations of the stars in a way detectable with the naked eye over many tens of thousands of years or more.) This means that from the viewpoint of an observer on the earth, the celestial sphere appears to rotate around him or her once a day, with all the stars affixed to it. (The fact that the observer is not at the center of the earth is of little consequence except in the case of the moon, for which lunar parallax must be taken into account before we can determine the position of the moon in the sky, either now or in the past.)