Beyond this, the accuracy of the date depends on the reliability of the assumptions used in interpreting the measurements (see below).Ĭarbon-14 dates usually appear to be reasonably accurate whenever they can be checked against historical records. This can be done very accurately, although some samples may be difficult to work with. The experimental part of 14C dating consists of measuring the amounts of carbon-14 and carbon-12, and sometimes C-13, in a sample. Carbon-14 dating does not produce ages in the millions of years, as do some other types of radioisotope dating. It is sometimes thought possible to extend the dating range a few half-lives, so one occasionally sees dates as old as 70,000 years or more. Ten half-lives of 14C makes about 57,300 years, so most 14C dates are less than that figure. After approximately ten half-lives, the amount of 14C becomes so small it is difficult to measure. Most limestone, diamonds, coal and oil are expected to have no residual 14C because of their presumed age, so they are not usually used in radiocarbon dating. It is not used to date rocks or other inorganic material.Ĭarbon-14 dating cannot be applied to materials that have no 14C. It is widely used in dating fossils or archaeological samples containing organic material such as wood, charcoal, bone, shells, etc. What materials can be dated by carbon-14?Ĭarbon-14 is used to date materials that were once living and still contain measurable amounts of 14C atoms. The standard calibration curve deviates significantly from the dates arrived at by assuming knowledge of initial 14C concentrations and a constant decay rate. In practice, the level of 14C in a sample is compared to a standard calibration curve constructed by measuring the 14C present in samples of known age. Usually the raw carbon-14 age of a sample is not thought to be the actual age. This is the (uncorrected) carbon-14 age of the sample. Scientists can measure the concentration of 14C in a sample with a high degree of accuracy and then calculate how long it would take for the concentration of 14C in the sample to decline from an assumed starting level to the level measured in the sample. The longer the time since death, the more of the 14C will have decayed, so the less 14C remains in the body. When organisms die, the 14C in their bodies is no longer replaced, so the level of 14C declines as it decays to 14N. Living organisms take in carbon, in the form of carbon dioxide, through their food and water, thus maintaining the same level of 14C in their bodies as is in their environment. The constant decay rate allows scientists to calculate the time required for the 14C level in a sample to reach a given concentration. The modern level is about 1 atom of 14C in every trillion carbon atoms. When the rates of 14C formation and decay reach equilibrium, the concentration of 14C in the atmosphere reaches a constant level. The rate of decay is such that half the atoms of carbon-14 in a sample decay to nitrogen in approximately 5730 years. The 14C is unstable (radioactive) and eventually decays back to nitrogen-14. Carbon-14 is formed in the upper atmosphere when a neutron in cosmic radiation strikes an atom of nitrogen-14 ( 14N) and converts it to carbon-14. What is the basis of carbon-14 dating?Ĭarbon exists in three forms, or isotopes, carbon-12 ( 12C), carbon-13 ( 13C), and carbon-14 ( 14C).
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |