Radioactive decay from lead-212 (212Pb) to lead-208 (208Pb) . Each parent nuclide spontaneously decays into a daughter nuclide (the
decay product) via an
α decay or a
β− decay. The final decay product, lead-208 (208Pb), is stable and can no longer undergo spontaneous radioactive decay. All ordinary
matter is made up of combinations of
chemical elements, each with its own
atomic number, indicating the number of
protons in the
atomic nucleus. Additionally, elements may exist in different
isotopes, with each isotope of an element differing in the number of
neutrons in the nucleus. A particular isotope of a particular element is called a
nuclide. Some nuclides are inherently unstable. That is, at some point in time, an atom of such a nuclide will undergo
radioactive decay and spontaneously transform into a different nuclide. This transformation may be accomplished in a number of different ways, including
alpha decay (emission of
alpha particles) and
beta decay (
electron emission,
positron emission, or
electron capture). Another possibility is
spontaneous fission into two or more nuclides. While the moment in time at which a particular nucleus decays is unpredictable, a collection of atoms of a radioactive nuclide decays
exponentially at a rate described by a parameter known as the
half-life, usually given in units of years when discussing dating techniques. After one half-life has elapsed, one half of the atoms of the nuclide in question will have decayed into a "daughter" nuclide or
decay product. In many cases, the daughter nuclide itself is radioactive, resulting in a
decay chain, eventually ending with the formation of a stable (nonradioactive) daughter nuclide; each step in such a chain is characterized by a distinct half-life. In these cases, usually the half-life of interest in radiometric dating is the longest one in the chain, which is the rate-limiting factor in the ultimate transformation of the radioactive nuclide into its stable daughter. Isotopic systems that have been exploited for radiometric dating have half-lives ranging from only about 10 years (e.g.,
tritium) to over 100 billion years (e.g.,
samarium-147). For most radioactive nuclides, the half-life depends solely on nuclear properties and is essentially constant. This is known because decay constants measured by different techniques give consistent values within analytical errors and the ages of the same materials are consistent from one method to another. It is not affected by external factors such as
temperature,
pressure, chemical environment, or presence of a
magnetic or
electric field. The only exceptions are nuclides that decay by the process of electron capture, such as
beryllium-7,
strontium-85, and
zirconium-89, whose decay rate may be affected by local electron density. For all other nuclides, the proportion of the original nuclide to its decay products changes in a predictable way as the original nuclide decays over time. This predictability allows the relative abundances of related nuclides to be used as a
clock to measure the time from the incorporation of the original nuclides into a material to the present.
Decay constant determination The radioactive decay constant, the probability that an atom will decay per year, is the solid foundation of the common measurement of radioactivity. The accuracy and precision of the determination of an age (and a nuclide's half-life) depends on the accuracy and precision of the decay constant measurement. The in-growth method is one way of measuring the decay constant of a system, which involves accumulating daughter nuclides. Unfortunately for nuclides with high decay constants (which are useful for dating very old samples), long periods of time (decades) are required to accumulate enough decay products in a single sample to accurately measure them. A faster method involves using particle counters to determine alpha, beta or gamma activity, and then dividing that by the number of radioactive nuclides. However, it is challenging and expensive to accurately determine the number of radioactive nuclides. Alternatively, decay constants can be determined by comparing isotope data for rocks of known age. This method requires at least one of the isotope systems to be very precisely calibrated, such as the
Pb–Pb system.
Accuracy of radiometric dating used in radiometric dating. The basic equation of radiometric dating requires that neither the parent nuclide nor the daughter product can enter or leave the material after its formation. The possible confounding effects of contamination of parent and daughter isotopes have to be considered, as do the effects of any loss or gain of such isotopes since the sample was created. It is therefore essential to have as much information as possible about the material being dated and to check for possible signs of
alteration. Precision is enhanced if measurements are taken on multiple samples from different locations of the rock body. Alternatively, if several different minerals can be dated from the same sample and are assumed to be formed by the same event and were in equilibrium with the reservoir when they formed, they should form an
isochron. This can reduce the problem of
contamination. In
uranium–lead dating, the
concordia diagram is used which also decreases the problem of nuclide loss. Finally, correlation between different isotopic dating methods may be required to confirm the age of a sample. For example, the age of the
Amitsoq gneisses from western Greenland was determined to be 3.60 ± 0.05
Ga (billion years ago) using uranium–lead dating and 3.56 ± 0.10 Ga (billion years ago) using lead–lead dating, results that are consistent with each other. Accurate radiometric dating generally requires that the parent has a long enough half-life that it will be present in significant amounts at the time of measurement (except as described below under "Dating with short-lived extinct radionuclides"), the half-life of the parent is accurately known, and enough of the daughter product is produced to be accurately measured and distinguished from the initial amount of the daughter present in the material. The procedures used to isolate and analyze the parent and daughter nuclides must be precise and accurate. This normally involves
isotope-ratio mass spectrometry. The precision of a dating method depends in part on the half-life of the radioactive isotope involved. For instance, carbon-14 has a half-life of 5,730 years. After an organism has been dead for 60,000 years, so little carbon-14 is left that accurate dating cannot be established. On the other hand, the concentration of carbon-14 falls off so steeply that the age of relatively young remains can be determined precisely to within a few decades.
Closure temperature The closure temperature or blocking temperature represents the temperature below which the mineral is a closed system for the studied isotopes. If a material that selectively rejects the daughter nuclide is heated above this temperature, any daughter nuclides that have been accumulated over time will be lost through
diffusion, resetting the isotopic "clock" to zero. As the mineral cools, the crystal structure begins to form and diffusion of isotopes is less easy. At a certain temperature, the crystal structure has formed sufficiently to prevent diffusion of isotopes. Thus an igneous or metamorphic rock or melt, which is slowly cooling, does not begin to exhibit measurable radioactive decay until it cools below the closure temperature. The age that can be calculated by radiometric dating is thus the time at which the rock or mineral cooled to closure temperature. This temperature varies for every mineral and isotopic system, so a system can be
closed for one mineral but
open for another. Dating of different minerals and/or isotope systems (with differing closure temperatures) within the same rock can therefore enable the tracking of the thermal history of the rock in question with time, and thus the history of metamorphic events may become known in detail. These temperatures are experimentally determined in the lab by
artificially resetting sample minerals using a high-temperature furnace. This field is known as
thermochronology or thermochronometry.
The age equation isochrons plotted of meteorite samples. The age is calculated from the slope of the isochron (line) and the original composition from the intercept of the isochron with the y-axis. The mathematical expression that relates radioactive decay to geologic time is where • is age of the sample, • is number of atoms of the radiogenic daughter isotope in the sample, • is number of atoms of the daughter isotope in the original or initial composition, • is number of atoms of the parent isotope in the sample at time (the present), given by , and • is the
decay constant of the parent isotope, equal to the inverse of the radioactive
half-life of the parent isotope times the natural logarithm of 2. The equation is most conveniently expressed in terms of the measured quantity
N(
t) rather than the constant initial value
No. To calculate the age, it is assumed that the system is
closed (neither parent nor daughter isotopes have been lost from system),
D0 either must be negligible or can be accurately estimated,
λ is known to high precision, and one has accurate and precise measurements of D* and
N(
t). The above equation makes use of information on the composition of parent and daughter isotopes at the time the material being tested cooled below its
closure temperature. This is well established for most isotopic systems. However, construction of an isochron does not require information on the original compositions, using merely the present ratios of the parent and daughter isotopes to a standard isotope. An
isochron plot is used to solve the age equation graphically and calculate the age of the sample and the original composition. ==Modern dating methods==