Radiometric dating By measuring the amount of
radioactive decay of a
radioactive isotope with a known
half-life, geologists can establish the absolute age of the parent material. A number of radioactive isotopes are used for this purpose, and depending on the rate of decay, are used for dating different geological periods. More slowly decaying isotopes are useful for longer periods of time, but less accurate in absolute years. With the exception of the
radiocarbon method, most of these techniques are actually based on measuring an increase in the abundance of a
radiogenic isotope, which is the decay-product of the radioactive parent isotope. Two or more radiometric methods can be used in concert to achieve more robust results. Most radiometric methods are suitable for geological time only, but some such as the radiocarbon method and the 40Ar/39Ar dating method can be extended into the time of early human life and into recorded history. Some of the commonly used techniques are: •
Radiocarbon dating. This technique measures the decay of
carbon-14 in organic material and can be best applied to samples younger than about 60,000 years. •
Uranium–lead dating. This technique measures the ratio of two lead
isotopes (lead-206 and lead-207) to the amount of uranium in a mineral or rock. Often applied to the trace mineral
zircon in
igneous rocks, this method is one of the two most commonly used (along with
argon–argon dating) for geologic dating.
Monazite geochronology is another example of U–Pb dating, employed for dating metamorphism in particular. Uranium–lead dating is applied to samples older than about 1 million years. •
Uranium–thorium dating. This technique is used to date
speleothems,
corals,
carbonates, and fossil
bones. Its range is from a few years to about 700,000 years. •
Potassium–argon dating and
argon–argon dating. These techniques date
metamorphic,
igneous and
volcanic rocks. They are also used to date
volcanic ash layers within or overlying
paleoanthropologic sites. The younger limit of the argon–argon method is a few thousand years. •
Electron spin resonance (ESR) dating
Fission-track dating Cosmogenic nuclide geochronology A series of related techniques for determining the age at which a geomorphic surface was created (
exposure dating), or at which formerly
surficial materials were buried (burial dating). Exposure dating uses the concentration of exotic nuclides (e.g. 10Be, 26Al, 36Cl) produced by cosmic rays interacting with Earth materials as a proxy for the age at which a surface, such as an alluvial fan, was created. Burial dating uses the differential radioactive decay of 2 cosmogenic elements as a proxy for the age at which a sediment was screened by burial from further cosmic rays exposure.
Luminescence dating Luminescence dating techniques observe 'light' emitted from materials such as quartz, diamond, feldspar, and calcite. Many types of luminescence techniques are utilized in geology, including
optically stimulated luminescence (OSL),
cathodoluminescence (CL), and
thermoluminescence (TL). Thermoluminescence and optically stimulated luminescence are used in archaeology to date 'fired' objects such as pottery or cooking stones and can be used to observe sand migration.
Incremental dating Incremental dating techniques allow the construction of year-by-year annual chronologies, which can be fixed (
i.e. linked to the present day and thus
calendar or
sidereal time) or floating. •
Dendrochronology •
Ice cores •
Lichenometry •
Varves
Paleomagnetic dating A sequence of
paleomagnetic poles (usually called virtual geomagnetic poles), which are already well defined in age, constitutes an
apparent polar wander path (APWP). Such a path is constructed for a large continental block. APWPs for different continents can be used as a reference for newly obtained poles for the rocks with unknown age. For paleomagnetic dating, it is suggested to use the APWP in order to date a pole obtained from rocks or sediments of unknown age by linking the paleopole to the nearest point on the APWP. Two methods of paleomagnetic dating have been suggested: (1) the angular method and (2) the rotation method. The first method is used for paleomagnetic dating of rocks inside of the same continental block. The second method is used for the folded areas where tectonic rotations are possible.
Magnetostratigraphy Magnetostratigraphy determines age from the pattern of magnetic polarity zones in a series of bedded sedimentary and/or volcanic rocks by comparison to the magnetic polarity timescale. The polarity timescale has been previously determined by dating of seafloor magnetic anomalies, radiometrically dating volcanic rocks within magnetostratigraphic sections, and astronomically dating magnetostratigraphic sections.
Chemostratigraphy Global trends in isotope compositions, particularly carbon-13 and strontium isotopes, can be used to correlate strata.
Correlation of marker horizons . The thick and light-to-dark coloured layer at the height of the
volcanologist's hands is a marker horizon of
rhyolitic-to-
basaltic
tephra from
Hekla.
Marker horizons are stratigraphic units of the same age and of such distinctive composition and appearance that, despite their presence in different geographic sites, there is certainty about their age-equivalence. Fossil faunal and floral
assemblages, both marine and terrestrial, make for distinctive marker horizons.
Tephrochronology is a method for geochemical correlation of unknown volcanic ash (tephra) to geochemically fingerprinted, dated
tephra. Tephra is also often used as a dating tool in archaeology, since the dates of some eruptions are well-established. == Interval hierarchy ==