ANTH 202 Week07-08 Dating Methods PDF

Summary

This document covers various dating methods used in anthropology and archaeology. It details the principles of relative dating, such as the principle of superposition and index fossils. Furthermore, it describes absolute dating methods, including radiocarbon dating and dendrochronology. The document aims to give students of anthropology a comprehensive overview of the methodologies employed to determine the age of artifacts and sites.

Full Transcript

Chronology

The study of historical records to establish the dates of past events
The arrangement of events in time
A timeline of events

(1) Relative – “this is older than that”
(example: Stone Age, Bronze Age, Iron Age)

Principle of Superposition – deeper layers are older than layers that
overlie them
Principle of Superposition
 Chronology
(1) Relative – “this is older
than that”
(example: Stone Age,
Bronze Age, Iron Age)

Principle of Superposition –
deeper, underlying levels
are older than those that
overlie them
Index fossil concept – strata
containing similar fossils
are of similar age
(instead of fossils,
archaeologists use
particular kinds of
artifacts as diagnostic
time markers)
Chronology
Seriation – putting artifacts
into a series or sequence
based on changes in form
and style, based on their
occurrence in stratigraphy –
or based on their
associations with other
objects that have secure
dates
Chronology
Seriation – putting artifacts
into a series or sequence
based on changes in form
and style, based on their
occurrence in stratigraphy –
or based on their
associations with other
objects that have secure
dates
Chronology
(1) Relative – “this is older
than that”
(example: Stone Age,
Bronze Age, Iron Age)

Principle of Superposition –
deeper, underlying levels
are older than those that
overlie them
Index fossil concept – strata
containing similar fossils
are of similar age
(instead of fossils,
archaeologists use
particular kinds of
artifacts as diagnostic
time markers)
“Battleship curves”
Seriation
 Chronology
(1) Relative – “this is older than that”
(example: Stone Age, Bronze Age, Iron Age)

Principle of Superposition – deeper, underlying levels are older
than those that overlie them
Index fossil concept – strata containing similar fossils are of
similar age (instead of fossils, archaeologists use particular
kinds of artifacts as diagnostic time markers)

Relative dating techniques:
Seriation – putting artifacts into a series or sequence based
on changes in form and style, based on their occurrence in
stratigraphy – or based on their associations with other
objects that have secure dates
Cross-dating – fit the sequence from a new “unknown” site
into sequences from known sites, using index fossil concept
Fishtail projectile point

Photo: Erica Cooper
 andesite

Cuncaicha

Morrow and Morrow, 1999. American
Fishtail projectile
Antiquity points are dated to 12,900-
64: 215-230.
12,200 years ago based on finding them in
association with 14C-dated organic remains in after Grosjean et al., 2005.
multiple sites in South America Journal of Quaternary Science
 Chronology

(2) Absolute – “how much this is older than that”
(example: Paleoindian sites date between 14,000-11,000
years old in North America, pottery appears about 4000
years ago in the Andes mountains)

Absolute dating methods:
potassium-argon (K-Ar) and argon-argon (Ar-Ar)
trapped-charge dating (thermoluminescence, optically
stimulated luminescence, electron spin resonance)
radiocarbon (14C)
dendrochronology
historical artifacts and written records
Absolute Dating
 Absolute Dating Methods
Dendrochronology (tree-ring dating) - uses a sequence of annual growth
rings of trees, can be used
to date archaeological wood

Bristlecone pine, max. ~8000 years old
Oldest living organism on Earth! (oldest
currently living is 5065 years old)
Archaeological wood at
Pueblo Bonito, Chaco
Canyon, NM
 Dendrochronology

Image courtesy
Crow Canyon
archaeological
center
 cosmic rays
14C 14N
14C + O2 14CO
2
Radiocarbon dating

14Cinto plants by
photosynthesis

after death:
no addition of atmospheric 14C,
radioactive decay of existing 14C
98.8% of carbon is 12C
1.1% of carbon is 13C
Only 0.0000000001% of
the carbon in today’s
atmosphere is 14C

14Chas a half life of 5730
years

14Cdates are reported as
before present (BP) where
present = AD/CE 1950
14C – organic remains (wood, charcoal, shell, bone, fiber, hair, hide, etc.)
 14C Dating - Measurement

Decay counting is relatively insensitive and subject to large statistical
uncertainties for small samples. When there is little 14C to begin with, the
long radiocarbon half-life means that very few of the 14C atoms will
decay during the time allotted for their detection, resulting in few
disintegrations per minute.

Accelerator Mass Spectrometry (AMS) 14C atoms can be detected and
counted directly vs. only detecting those atoms that decay during the
time interval allotted for an analysis. AMS allows dating samples
containing only a few milligrams of carbon.

Radiocarbon dating laboratories generally report an uncertainty for each
date. For example, 3000 ± 30 BP indicates a standard deviation of 30
radiocarbon years. This uncertainty is the sum of the lab statistical
counting uncertainties and is determined by running a standard sample
of known age for comparison.
 14C Dating – Limits and Calibration

Limit of ~40,000 years for conventional method, ~45,000 years for AMS

More uncertainty! – amount of 14C in atmosphere has not been constant
but has fluctuated through time, requiring the use of calibration of
radiocarbon years to calendar years using ice cores, tree rings, varves
(see next slide) dated by other methods

Reservoir effects – dating organic materials from the ocean or deep
lakes (for example, shellfish, aquatic plants) can be problematic
because when alive, organisms are taking in very old, 14C-depleted CO2
Varves

Light layers = summer
(Heavier silicates carried by
meltwater)

Dark layers = winter
(Clay that settled out of
water)
14C Dating
The 14C level in the atmosphere is
affected by:
variations in the cosmic ray
intensity
variations in the Earth's
magnetosphere
Carbon uptake/release in organic
matter, the ocean, ocean
sediments (see methane
hydrate), and sedimentary rocks,
which fluctuates with glacial and
interglacial episodes.
Detailed charting of glacial cycles over the last million
years, according to isotopic oxygen analyses of
foraminifera (SPECMAP project). The different marine
isotopic stages are indicated numerically (MIS). During
the warm interglacial periods (red numbers) the
isotopic ratio of oxygen-18 in both seawater and
foraminifer shells dropped (note that the horizontal
scale is inverted). During the glacial periods (blue
numbers) however, it increased.
 14C Dating – Calibration

The 14C level in the atmosphere
has also been affected by human
activities. From the beginning of
the Industrial Revolution in the
18th century to the 1950s, the
fractional level of 14C decreased
because of the admixture of large
quantities of “dead” CO2 into the
atmosphere, due to the excavated
oil reserves and combustion
production of fossil fuel (fossil
fuels are so old that there is no
remaining 14C).

This is called the Suess effect
named for the Austrian
chemist Hans Suess, who
discovered it.

Not Dr. Seuss, who wrote
terrific books for kids
 14C Dating – Calibration

The 14C level in the atmosphere
has also been affected by human
activities. From the beginning of
the industrial revolution in the
18th century to the 1950s, the
fractional level of 14C decreased
because of the admixture of large
quantities of “dead” CO2 into the
atmosphere, due to the excavated
oil reserves and combustion
production of fossil fuel (fossil
fuels are so old that there is no
remaining 14C).

Atmospheric 14C was almost
doubled for a short period during
the 1950s and 1960s due to
atmospheric atomic bomb tests.
That effect is decreasing
gradually.
Absolute Dating
 Laetoli, Tanzania
Hominid footprint
3.6 ma

K-Ar dating, Ar-Ar dating
dates volcanic rocks, ash
deposits
4.5 billion – 100,000 B.P.
Tephra: airborne volcanic debris

Radioactive isotope 40K decays with a
half-life of 1.248×109 years to 40Ca
and 40Ar

The amount of Ar is measured by mass
spectrometry of the gases released
when a rock sample is volatilized in
vacuum.

Potassium is quantified by flame
photometry or atomic absorption
spectroscopy.
 Absolute Dating

Trapped charge dating – background gamma radiation from the decay
of uranium, thorium, potassium in sediments causes electrons to
be trapped in crystal lattices in quartz sands and feldspars. The
trapped electrons accumulate over time. Measuring the amount
of the trapped electrons gives you an estimate of the age of the
sample.
How is this done?
1) Experimentally determine the background radiation that
accumulates annually using a dosimeter
2) Expose the sediment sample to light or heat, which frees the
trapped electrons. These electrons generate light, which is
measured and yields the estimate of the amount of trapped
electrons.

Thermoluminescence
Optically stimulated luminescence
Electron spin resonance
 Absolute Dating

Thermoluminescence dating – used on kiln-fired ceramics, hearth
sediments, burned artifacts. Dates the last time an object was
burned at 500 degrees celsius.
Heat the sample to 500 degrees C and measure emitted light

Optically stimulated luminescence – used on sediments. Dates the last
time a sediment was exposed to sunlight, which is also the time
it was first buried
Expose the sediment to sunlight and measure emitted light

Electron spin resonance dating – used on tooth enamel. Dates the last
time the tooth (and the person to whom it belonged) was
buried.
Expose the sample to electromagnetic radiation and measure the
amount absorbed by the sample