# Carbon dating mathematics formula

In this section we will explore the use of carbon dating to determine the age of fossil remains. Carbon is a key Carbon dating mathematics formula

in biologically important molecules. During the lifetime of an organism, carbon is brought *Carbon dating mathematics formula* the Carbon dating mathematics formula from the environment in the form of either carbon dioxide or carbon-based food molecules such as glucose; then used to build biologically important molecules such as sugars, proteins, fats, and nucleic acids.

These molecules are subsequently incorporated into the *Carbon dating mathematics formula* and tissues that make up living things.

Therefore, organisms from a single-celled Carbon dating mathematics formula to the largest of the dinosaurs leave behind carbon-based remains. Carbon dating is based upon the decay of 14 C, a radioactive isotope of carbon with a relatively long half-life years. While 12 C *Carbon dating mathematics formula* the most abundant carbon isotope, there is a close to Carbon dating mathematics formula ratio of 12 C to 14 C in the environment, and hence in the molecules, cells, and tissues of living organisms.

This constant ratio is maintained until the death of an organism, when 14 C stops being replenished. At this point, the overall amount of 14 C in the Carbon dating mathematics formula begins to decay exponentially. Therefore, by knowing the amount of 14 C in fossil remains, you *Carbon dating mathematics formula* determine how long ago an organism died by examining the departure of the observed 12 C to 14 C ratio from the expected ratio for a living Carbon dating mathematics formula. Radioactive isotopes, such as 14 C, decay exponentially.

The half-life of an isotope is defined as the amount of time it takes for there to be half the initial amount Carbon dating mathematics Carbon dating mathematics formula

the radioactive isotope present.

We can use our our general model for exponential decay to calculate the amount of carbon at any given time using the equation. Returning to our example of carbon, knowing that the half-life of 14 C is years, we can use this to find the constant, k.

Thus, we can write:. Simplifying this expression by canceling the N 0 on both sides of the equation gives. Solving for Carbon dating mathematics formula

unknown, kwe take the natural logarithm of both sides. Other radioactive isotopes are also used to date fossils.

The half-life for 14 C is approximately years, therefore the 14 C isotope is only useful for dating fossils up to about 50, years old. Fossils older than 50, years may have an undetectable amount of 14 C. For older fossils, an isotope with a longer half-life should be used.

Carbon dating mathematics formula example, the radioactive isotope potassium decays to argon with a half life of 1. Other isotopes commonly used for dating include uranium half-life of 4. Problem 1- Calculate the amount of 14 C remaining in a sample. Problem 2- Calculate the age of a fossil.

Problem 3- Calculate the initial amount of 14 C in a fossil. Problem 4 - Carbon dating mathematics formula

the age of a fossil. Problem 5- Calculate the amount of 14 *Carbon dating mathematics formula* remaining after a given time has passed. Decay of radioactive isotopes Radioactive isotopes, such Carbon dating mathematics formula 14 C, decay exponentially.

Modeling the decay of 14 C. Thus, we can write: Thus, our equation for modeling the decay of 14 C is given by.