{"id":370,"date":"2019-06-11T14:50:15","date_gmt":"2019-06-11T14:50:15","guid":{"rendered":"https:\/\/opentextbc.ca\/physicalgeology2ed\/chapter\/8-4-isotopic-dating-methods\/"},"modified":"2021-12-07T23:51:26","modified_gmt":"2021-12-07T23:51:26","slug":"8-4-isotopic-dating-methods","status":"publish","type":"chapter","link":"https:\/\/opentextbc.ca\/physicalgeology2ed\/chapter\/8-4-isotopic-dating-methods\/","title":{"raw":"8.4 Isotopic Dating Methods","rendered":"8.4 Isotopic Dating Methods"},"content":{"raw":"Originally fossils only provided us with relative ages because, although early paleontologists understood biological succession, they did not know the absolute ages of the different organisms. It was only in the early part of the 20th century, when isotopic dating methods were first applied, that it became possible to discover the absolute ages of the rocks containing fossils. In most cases, we cannot use isotopic techniques to directly date fossils or the sedimentary rocks they are found in, but we can constrain their ages by dating igneous rocks that cut across sedimentary rocks, or volcanic layers that lie within sedimentary layers.<\/a>\r\n\r\n[caption id=\"attachment_364\" align=\"alignright\" width=\"500\"]\"\"<\/a> Figure 8.4.1 The decay of 40<\/sup>K over time. Each half-life is 1.3 billion years, so after 3.9 billion years (three half-lives) 12.5% of the original 40<\/sup>K will remain. The red-blue bars represent 40<\/sup>K and the green-yellow bars represent 40<\/sup>Ar. [Image Description]<\/a>[\/caption]Isotopic dating of rocks, or the minerals in them, is based on the fact that we know the decay rates of certain unstable [pb_glossary id=\"1577\"]isotopes[\/pb_glossary]<\/strong> of elements and that these rates have been constant over geological time. It is also based on the premise that when the atoms of an element decay within a mineral or a rock, they stay there and don\u2019t escape to the surrounding rock, water, or air. One of the isotope pairs widely used in geology is the decay of 40<\/sup>K to 40<\/sup>Ar (potassium-40 to argon-40). 40<\/sup>K is a radioactive isotope of potassium that is present in very small amounts in all minerals that have potassium in them. It has a half-life of 1.3 billion years, meaning that over a period of 1.3 Ga one-half of the 40<\/sup>K atoms in a mineral or rock will decay to 40<\/sup>Ar, and over the next 1.3 Ga one-half of the remaining atoms will decay, and so on (Figure 8.4.1).\r\n\r\nIn order to use the K-Ar dating technique, we need to have an igneous or metamorphic rock that includes a potassium-bearing mineral. One good example is granite, which normally has some potassium feldspar (Figure 8.4.2). Feldspar does not have any argon in it when it forms. Over time, the 40<\/sup>K in the feldspar decays to 40<\/sup>Ar. Argon is a gas and the atoms of 40<\/sup>Ar remain embedded within the crystal, unless the rock is subjected to high temperatures after it forms. The sample must be analyzed using a very sensitive mass-spectrometer, which can detect the differences between the masses of atoms, and can therefore distinguish between 40<\/sup>K and the much more abundant 39<\/sup>K. Biotite and hornblende are also commonly used for K-Ar dating.\r\n\r\n[caption id=\"attachment_365\" align=\"aligncenter\" width=\"766\"]\"\"<\/a> Figure 8.4.2 Crystals of potassium feldspar (pink) in a granitic rock are candidates for isotopic dating using the K-Ar method because they contained potassium and no argon when they formed.[\/caption]\r\n\r\n
Why can\u2019t we use isotopic dating techniques to accurately date sedimentary rocks?<\/strong><\/header>\r\n
\r\n\r\n[caption id=\"attachment_366\" align=\"aligncenter\" width=\"678\"]\"\"<\/a> Figure 8.4.3[\/caption]\r\n\r\nAn important assumption that we have to be able to make when using isotopic dating is that when the rock formed none of the daughter isotope was present (e.g., 40<\/sup>Ar in the case of the K-Ar method). A clastic sedimentary rock is made up of older rock and mineral fragments, and when the rock forms it is almost certain that all of the fragments already have daughter isotopes in them. Furthermore, in almost all cases, the fragments have come from a range of source rocks that all formed at different times. If we dated a number of individual grains in the sedimentary rock, we would likely get a range of different dates, all older than the age of the rock.\u00a0 That could be useful information, but it would not provide an accurate date for the rock in question.\r\n\r\nIt might be possible to directly date some chemical sedimentary rocks isotopically, but there are no useful isotopes that can be used on old chemical sedimentary rocks. Radiocarbon dating can be used on sediments or sedimentary rocks that contain carbon, but it cannot be used on materials older than about 60 ka.\r\n\r\n<\/div>\r\n<\/div>\r\nK-Ar is just one of many isotope-pairs that are useful for dating geological materials. Some of the other important pairs are listed in Table 8.2, along with the age ranges that they apply to and some comments on their applications. When radiometric techniques are applied to metamorphic rocks, the results normally tell us the date of metamorphism, not the date when the parent rock formed.\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n
Table 8.2 A few of the isotope systems that are widely used for dating geological materials<\/caption>\r\n
[Skip Table]<\/a><\/td>\r\n<\/tr>\r\n
Isotope System<\/th>\r\nHalf-Life<\/th>\r\nUseful Range<\/th>\r\nComments<\/th>\r\n<\/tr>\r\n<\/thead>\r\n
Potassium-argon<\/td>\r\n1.3 Ga<\/td>\r\n10 Ka to 4.57 Ga<\/td>\r\nWidely applicable because most rocks have some potassium<\/td>\r\n<\/tr>\r\n
Uranium-lead<\/td>\r\n4.5 Ga<\/td>\r\n1 Ma to 4.57 Ga<\/td>\r\nThe rock must have uranium-bearing minerals, but most have enough.<\/td>\r\n<\/tr>\r\n
Rubidium-strontium<\/td>\r\n47 Ga<\/td>\r\n10 Ma to 4.57 Ga<\/td>\r\nLess precision than other methods at old dates<\/td>\r\n<\/tr>\r\n
Carbon-nitrogen (a.k.a. radiocarbon dating)<\/td>\r\n5,730 years<\/td>\r\n100 to 60,000 years<\/td>\r\nSample must contain wood, bone, or carbonate minerals; can be applied to young sediments<\/td>\r\n<\/tr>\r\n<\/tbody>\r\n<\/table>\r\n
\r\n

Exercise 8.3 Isotopic dating<\/p>\r\n\r\n<\/header>\r\n

\r\n\r\nAssume that a feldspar crystal from the granite shown in Figure 8.4.2 was analyzed for 40<\/sup>K and 40<\/sup>Ar. The proportion of 40<\/sup>K remaining is 0.91. Using the decay curve shown on the graph below, estimate the age of the rock.<\/a>\r\n\r\n[caption id=\"attachment_367\" align=\"alignnone\" width=\"776\"]\"\"<\/a> Figure 8.4.4 [Image Description]<\/a>[\/caption]An example is provided (in blue) for a 40<\/sup>K proportion of 0.95, which is equivalent to an age of approximately 96 Ma.\u00a0This is determined by drawing a horizontal line from 0.95 to the decay curve line, and then a vertical line from there to the time axis.See Appendix 3 for Exercise 8.3 answers<\/a>.\r\n\r\n<\/div>\r\n<\/div>\r\n\r\n[caption id=\"attachment_368\" align=\"aligncenter\" width=\"773\"]\"\"<\/a> Figure 8.4.5 Radiocarbon dates on wood fragments in glacial sediments in the Strait of Georgia.[\/caption]\r\n\r\nRadiocarbon dating (using 14<\/sup>C) can be applied to many geological materials, including sediments and sedimentary rocks, but the materials in question must be younger than 60 ka. Fragments of wood incorporated into young sediments are good candidates for carbon dating, and this technique has been used widely in studies involving late Pleistocene glaciers and glacial sediments. An example is shown in Figure 8.4.5; radiocarbon dates from wood fragments in glacial sediments have been used to estimate the timing of the last glacial advance along the Strait of Georgia.\u00a0 It is evident that the ice-front of the major glacier that occupied the Strait of Georgia was near to Campbell River at around 35 ka, near to Nanaimo and Vancouver at about 25 ka, and had reached the Victoria area by around 22 ka.\r\n\r\nOver the past decade there has been increasing use of U-Pb dating to study sedimentary rocks, not necessarily to find out the age of the rock, but to discover something about its history and origins.\u00a0 All clastic sedimentary rocks contain some tiny clasts of the silicate mineral zircon (ZrSiO4<\/sub>), derived from the weathering of the sediment parent rocks.\u00a0 Zircon always has some uranium in it (but no lead) so it is a good candidate for U-Pb dating, and it isn't too difficult to separate the grains of zircon from the other grains in a sandstone.\u00a0 The procedure is to isolate a few hundred tiny zircons from a rock sample, and then carry out U-Pb dating on each one of them.\u00a0 An example of the types of results obtained are shown on Figure 8.5.6.\u00a0 All of the samples are from Nanaimo Gp. rocks on Vancouver Island and nearby Salt Spring Island.\r\n\r\nThe three samples from Vancouver Island have zircons aged around 90 Ma, 118 Ma and 150 Ma.\u00a0 The Salt Spring Island sample has some zircons aged around 150 Ma, but most are much older, at 200 Ma and 340 to 360 Ma.\u00a0 It is interpreted that the younger zircons (90 to 150 Ma) are mostly derived from granitic rocks in the Coast Range, while the older ones (>200 Ma) are from older rocks on Vancouver Island (Huang, 2018).\r\n\r\n[caption id=\"attachment_369\" align=\"aligncenter\" width=\"584\"]\"\"<\/a> Figure 8.4.6 U-Pb dates for zircon samples from the Nanaimo Gp. (after Krause, 2018) a: a typical zircon clast (this one is about 1\/4 mm long).\u00a0 b: plots of zircon ages for 4 sandstone samples.[\/caption]\r\n

Image Descriptions<\/h3>\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n
<\/a>Figure 8.4.1 image description: Decay of 40K over time.<\/caption>\r\n
Number of half-lives<\/th>\r\nPercent of 40K remaining<\/th>\r\nPercent of 40Ar<\/th>\r\n<\/tr>\r\n<\/thead>\r\n
0<\/td>\r\n100<\/td>\r\n0<\/td>\r\n<\/tr>\r\n
1<\/td>\r\n50<\/td>\r\n50<\/td>\r\n<\/tr>\r\n
2<\/td>\r\n25<\/td>\r\n75<\/td>\r\n<\/tr>\r\n
3<\/td>\r\n12.5<\/td>\r\n87.5<\/td>\r\n<\/tr>\r\n
4<\/td>\r\n6.25<\/td>\r\n93.75<\/td>\r\n<\/tr>\r\n
5<\/td>\r\n3.125<\/td>\r\n96.875<\/td>\r\n<\/tr>\r\n
6<\/td>\r\n1.5625<\/td>\r\n98.4375<\/td>\r\n<\/tr>\r\n
7<\/td>\r\n0.78125<\/td>\r\n99.21875<\/td>\r\n<\/tr>\r\n<\/tbody>\r\n<\/table>\r\n[Return to Figure 8.4.1]<\/a>\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n
<\/a>Figure 8.4.4 image description: isotopic dating graph<\/caption>\r\n
Proportion of Potassium-40 remaining<\/th>\r\nAge (in millions of\u00a0 Years)<\/th>\r\n<\/tr>\r\n<\/thead>\r\n
1.00<\/td>\r\n0<\/td>\r\n<\/tr>\r\n
0.99<\/td>\r\n19<\/td>\r\n<\/tr>\r\n
0.98<\/td>\r\n37<\/td>\r\n<\/tr>\r\n
0.97<\/td>\r\n55<\/td>\r\n<\/tr>\r\n
0.96<\/td>\r\n75<\/td>\r\n<\/tr>\r\n
0.95<\/td>\r\n96<\/td>\r\n<\/tr>\r\n
0.94<\/td>\r\n114<\/td>\r\n<\/tr>\r\n
0.93<\/td>\r\n134<\/td>\r\n<\/tr>\r\n
0.92<\/td>\r\n156<\/td>\r\n<\/tr>\r\n
0.91<\/td>\r\n175<\/td>\r\n<\/tr>\r\n
0.90<\/td>\r\n194<\/td>\r\n<\/tr>\r\n<\/tbody>\r\n<\/table>\r\n[Return to Figure 8.4.4]<\/a>\r\n

Media Attributions<\/h3>\r\n