Carbon 14, Dendrochronology and Deep Time
This week we are visiting the topic
of archaeological time and how two scientific dating methods have vastly enhanced
our understanding of past human events.
It was principally through the research
of Willard F. Libby (1908-1980) (Anderson et al. 1947) that the method of
radiocarbon dating, an accurate, absolute method of dating organic substances from
archaeological, geological and environmental contexts, was developed. A key
thresh-hold leading to the radiocarbon dating method was the discovery of the Carbon
14 atom’s half-life of 5,730 years*. By comparing the known decay rate of C14 with
the amount of C14 remaining, Libby was able to calculate the age of the sample
up to approximately 45,000 to 50,000 years.
In 1948, following this
breakthrough, Libby and a committee of anthropologists and geologists under the
sponsorship of the American Anthropological Association tested different organic
materials of known ages. For example, the funeral boat cedar wood belonging to the
Egyptian pharaoh Sesostris, who died circa 3800 years B.P. (before the present).
Libby’s radiocarbon age confirmed the boat’s known age at 3,800 +/-180 B.P.
(Arnold and Libby 1949; Libby 1952; Poole 1961). Until Libby’s breakthrough
discoveries in the radiocarbon dating process scientists could only estimate
the age of archaeological/geological samples through relative means, such as
stratigraphy and an artifact’s association with something else. For his
pioneering research in the radiocarbon dating method Willard Libby was awarded the
Nobel Prize in 1960.
Extracting wood charcoal for carbon dating
Since
the discovery of radiocarbon dating its boundaries and accuracy has been enhanced
by other scientific disciplines, especially dendrochronology or the study of
tree ring patterns (Douglass 1919). Astronomer Andrew E. Douglass (1867-1962)
is considered the father of dendrochronology. His scientific approach to correlating
annular tree ring growth with solar (sun spot) activity subsequently led to other
branches of multidisciplinary studies involving climate change, human use of,
and adaptation to, the natural landscape, geological events, art and building
history and other related topics. On point, is that Douglass developed a precise
means by which he could bridge history to prehistory by working backward in
time using overlapping tree ring patterns observed in the cross sections of wood
beams. Much of his sampling took place at archaeological sites where roof beams
were preserved in the arid environment of the prehistoric southwest. Since Douglass’ pioneering, work much has
been accomplished by dendrochronologists to advance the dating method which
currently extends the chronology beyond 13,000 years (Ferguson 1970; Schulman
1956; Stuiver et al 1986).
Lab technician with sample specimen for dendrochronology dating
Radiocarbon Dates + Tree Rings = Calibrated Accuracy
Graph showing divergence between C14 and tree ring chronologies
The
multidisciplinary approach to dating archaeological samples using C14 and
dendrology dating has its limitations and is not the panacea to knowing the
exact age of something that has absorbed C14 during its entire life cycle. Fluctuations
in the amount of C14, solar radiation, nuclear bomb radiation, volcanic
activity etc., to name a few examples, can affect the true C14 age of a sample
depending on its age and geographic location and the calibration program(s)
used. Radiocarbon laboratories globally
have grappled with the problem by developing their own radiocarbon calibration
programs and several of these are available online (i.e OxCal and
CALPAL). Through diligence and refinement of these techniques, the applications
for dating organic samples can only improve. In light of these improvements in
dating methods, The State Museum of Pennsylvania reorganized its culture chronology
chart for Pennsylvania. Based on the
recalibrated radiocarbon dates that are now available the following table
provides our current culture chronology. Ages following AD.1000 are listed as
BP (before present).
* Note: Calculated
Libby half-life of C14 is 5568 years. Recalculated true half-life is
5730 years.
References:
Anderson, E.C., W. F. Libby et
al.
1947 Natural Radiocarbon from Cosmic Radiation. Physical Review
72:931
Arnold, J.R., and W.F. Libby
1949 Age Determination by Radiocarbon Content:
Checks with Samples of Known Age. Science 110:678.
Douglass,
A.E.
1919 Climatic Cycles and Tree Growth.
Vol. 1 No. 289, Washington, D.C. Carnegie Institution of Washington.
Ferguson,C.W.
1970 Dendrochronology of Bristlecone Pine, Pinus arisata. Proceedings of the
Twelfth Nobel Symposium, Upsala Sweden, August 11-15, 1969. Almquist and
Wiksell, Stockholm.
Libby,
W.F.
1952 Radiocarbon Dating. University of
Chicago Press.
Poole,
Lynn
1961 Carbon
– 14 and other Science Methods that Date the Past. Whittlesey House.
McGraw-Hill Book Company, Inc.For more information, visit PAarchaeology.state.pa.us or the Hall of Anthropology and Archaeology at The State Museum of Pennsylvania .
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