What is the difference between relative dating and absolute dating of fossils?

Main Difference
In the field of Geology, dating is an important term as it is a technique through which evaluation regarding the age and period about the fossil, remains, the archaeologists do valuables and artifacts. At first, there were not many methods of dating were available, but now with advancement in the technology, we mainly have two types of techniques to ascertain ages of ancient belongings. Relative Dating and Absolute Dating are two types of such techniques which are under practice to determine the age of the fossils, objects or civilizations. The relative dating is the technique in the Geology through which the age is determined with relation to the other objects. In other words, we can say that in relative dating the archaeologist determines that which of the two fossil or the artifacts are older. Contrary to this, absolute dating is the technique, using which the exact age of the artifacts, fossils, or sites are ascertained.

Relative dating is the technique used to know which object or item is older in comparison to the other one. Contrary to this, absolute dating is the technique which tells about the exact age of the artifact or the site using the methods like carbon dating.

The absolute dating is also known as numerical dating as it comes up with the exact numerical age of the item.

In relative dating techniques like stratigraphy and biostratigraphy are used to know which of the object is older. On the other hand, in absolute dating, methods like radiometric dating, carbon dating, and trapped electron method are used.

Relative Dating	Absolute Dating
Relative dating is the technique used to know which object or item is older in comparison to the other one.	The absolute dating is the technique which tells about the exact age of the artifact or the site using the methods like carbon dating.
Other Names
No other name.	Also known as numerical dating.
Methods
In relative dating techniques like stratigraphy and biostratigraphy are used to know which of the object is older.	Methods like radiometric dating, carbon dating, and trapped electron method are used.

The relative dating is the technique to ascertain the age of the artifacts, rocks or even sites while comparing one from the other. In relative dating the exact age of the object is not known; the only thing which made clear using this is that which of the two artifacts is older. Relative dating is a less advanced technique as compared to absolute dating. In relative dating, mostly the common sense principles are applied, and it is told that which artifact or object is older than the other one. Most commonly, the ancient factors of the rocks or objects are examined using the method called stratigraphy. In other words, we can say that the age in relative dating is ascertained by witnessing the layers of deposition or the rocks. As the word relative tells that defining the object with respect to the other object, it will be pertinent to mention here that actual numerical dates of the rocks or sites are not known in this type of dating. Other than rocks, fossils are the other most important elements in relative dating as many organisms have there remain in the sedimentary rocks. This evaluation of the rocks and fossils in relative dating is known as the biostratigraphy.

What is Absolute Dating?

The absolute dating is the technique to ascertain the exact numerical age of the artifacts, rocks or even sites, with using the methods like carbon dating and other. To evaluate the exact age, both the chemical and physical properties of the object are looked keenly. The main techniques used in absolute dating are carbon dating, annual cycle method, trapped electron method, and the atomic clocks. These techniques are more complex and advanced regarding technology as compared to the techniques in practice in relative dating. The absolute dating is also sometimes referred to as the relative numerical dating as it comes with the exact age of the object. The absolute dating is more reliable than the relative dating, which merely puts the different events in the time order and explains one using the other. Radiometric dating is another crucial technique through which the exact age can be obtained. In radiometric dating, the radioactive minerals within the rocks are used to know about the age of the object or the sites.

Unlike relative dating methods, absolute dating methods provide chronological estimates of the age of certain geological materials associated with fossils, and even direct age measurements of the fossil material itself. To establish the age of a rock or a fossil, researchers use some type of clock to determine the date it was formed. Geologists commonly use radiometric dating methods, based on the natural radioactive decay of certain elements such as potassium and carbon, as reliable clocks to date ancient events. Geologists also use other methods - such as electron spin resonance and thermoluminescence, which assess the effects of radioactivity on the accumulation of electrons in imperfections, or "traps," in the crystal structure of a mineral - to determine the age of the rocks or fossils.

All elements contain protons and neutrons, located in the atomic nucleus, and electrons that orbit around the nucleus (Figure 5a). In each element, the number of protons is constant while the number of neutrons and electrons can vary. Atoms of the same element but with different number of neutrons are called isotopes of that element. Each isotope is identified by its atomic mass, which is the number of protons plus neutrons. For example, the element carbon has six protons, but can have six, seven, or eight neutrons. Thus, carbon has three isotopes: carbon 12 (12C), carbon 13 (13C), and carbon 14 (14C) (Figure 5a).

Figure 5: Radioactive isotopes and how they decay through time.

(a) Carbon has three isotopes with different numbers of neutrons: carbon 12 (C12, 6 protons + 6 neutrons), carbon 13 (C13, 6 protons + 7 neutrons), and carbon 14 (C14, 6 protons + 8 neutrons). C12 and C13 are stable. The atomic nucleus in C14 is unstable making the isotope radioactive. Because it is unstable, occasionally C14 undergoes radioactive decay to become stable nitrogen (N14). (b) The radioactive atoms (parent isotopes) in any mineral decay over time into stable daughter isotopes. The amount of time it takes for half of the parent isotopes to decay into daughter isotopes is known as the half-life of the radioactive isotope.

Most isotopes found on Earth are generally stable and do not change. However some isotopes, like 14C, have an unstable nucleus and are radioactive. This means that occasionally the unstable isotope will change its number of protons, neutrons, or both. This change is called radioactive decay. For example, unstable 14C transforms to stable nitrogen (14N). The atomic nucleus that decays is called the parent isotope. The product of the decay is called the daughter isotope. In the example, 14C is the parent and 14N is the daughter.

Some minerals in rocks and organic matter (e.g., wood, bones, and shells) can contain radioactive isotopes. The abundances of parent and daughter isotopes in a sample can be measured and used to determine their age. This method is known as radiometric dating. Some commonly used dating methods are summarized in Table 1.

The rate of decay for many radioactive isotopes has been measured and does not change over time. Thus, each radioactive isotope has been decaying at the same rate since it was formed, ticking along regularly like a clock. For example, when potassium is incorporated into a mineral that forms when lava cools, there is no argon from previous decay (argon, a gas, escapes into the atmosphere while the lava is still molten). When that mineral forms and the rock cools enough that argon can no longer escape, the "radiometric clock" starts. Over time, the radioactive isotope of potassium decays slowly into stable argon, which accumulates in the mineral.

The amount of time that it takes for half of the parent isotope to decay into daughter isotopes is called the half-life of an isotope (Figure 5b). When the quantities of the parent and daughter isotopes are equal, one half-life has occurred. If the half life of an isotope is known, the abundance of the parent and daughter isotopes can be measured and the amount of time that has elapsed since the "radiometric clock" started can be calculated.

For example, if the measured abundance of 14C and 14N in a bone are equal, one half-life has passed and the bone is 5,730 years old (an amount equal to the half-life of 14C). If there is three times less 14C than 14N in the bone, two half lives have passed and the sample is 11,460 years old. However, if the bone is 70,000 years or older the amount of 14C left in the bone will be too small to measure accurately. Thus, radiocarbon dating is only useful for measuring things that were formed in the relatively recent geologic past. Luckily, there are methods, such as the commonly used potassium-argon (K-Ar) method, that allows dating of materials that are beyond the limit of radiocarbon dating (Table 1).

Name of Method	Age Range of Application	Material Dated	Methodology
Radiocarbon	1 - 70,000 years	Organic material such as bones, wood, charcoal, shells	Radioactive decay of 14C in organic matter after removal from bioshpere
K-Ar dating	1,000 - billion of years	Potassium-bearing minerals and glasses	Radioactive decay of 40K in rocks and minerals
Uranium-Lead	10,000 - billion of years	Uranium-bearing minerals	Radioactive decay of uranium to lead via two separate decay chains
Uranium series	1,000 - 500,000 years	Uranium-bearing minerals, corals, shells, teeth, CaCO3	Radioactive decay of 234U to 230Th
Fission track	1,000 - billion of years	Uranium-bearing minerals and glasses	Measurement of damage tracks in glass and minerals from the radioactive decay of 238U
Luminescence (optically or thermally stimulated)	1,000 - 1,000,000 years	Quartz, feldspar, stone tools, pottery	Burial or heating age based on the accumulation of radiation-induced damage to electron sitting in mineral lattices
Electron Spin Resonance (ESR)	1,000 - 3,000,000 years	Uranium-bearing materials in which uranium has been absorbed from outside sources	Burial age based on abundance of radiation-induced paramagnetic centers in mineral lattices
Cosmogenic Nuclides	1,000 - 5,000,000 years	Typically quartz or olivine from volcanic or sedimentary rocks	Radioactive decay of cosmic-ray generated nuclides in surficial environments
Magnetostratigraphy	20,000 - billion of years	Sedimentary and volcanic rocks	Measurement of ancient polarity of the earth's magnetic field recorded in a stratigraphic succession
Tephrochronology	100 - billions of years	Volcanic ejecta	Uses chemistry and age of volcanic deposits to establish links between distant stratigraphic successions
Table 1. Comparison of commonly used dating methods.

Radiation, which is a byproduct of radioactive decay, causes electrons to dislodge from their normal position in atoms and become trapped in imperfections in the crystal structure of the material. Dating methods like thermoluminescence, optical stimulating luminescence and electron spin resonance, measure the accumulation of electrons in these imperfections, or "traps," in the crystal structure of the material. If the amount of radiation to which an object is exposed remains constant, the amount of electrons trapped in the imperfections in the crystal structure of the material will be proportional to the age of the material. These methods are applicable to materials that are up to about 100,000 years old. However, once rocks or fossils become much older than that, all of the "traps" in the crystal structures become full and no more electrons can accumulate, even if they are dislodged.