They have examined rocks from the moon and from meteorites, neither of which have been altered by the rock cycle. To get around the difficulty presented by the rock cycle, scientists have looked elsewhere in the solar system for even older rock samples. The oldest rocks that have been found are about 3.8-billion years old, though some tiny minerals have been dated at 4.2 billion years. This makes finding an exact age for Earth difficult, because the original rocks that formed on the planet at the earliest stages of its creation are no longer here. Old rocks may even be destroyed as they slide back into Earth’s mantle, to be replaced by newer rocks formed by solidified lava. During the rock cycle, rocks are constantly changing between forms, going back and forth from igneous to metamorphic to sedimentary. One problem with this approach to dating rocks and minerals on Earth is the presence of the rock cycle. The age of a sample can be determined based on the ratio of parent to daughter isotopes within the sample. The half-life of an element is the amount of time required for exactly half of a quantity of that element to decay. The isotopes of unstable radioactive elements-known as parent isotopes-eventually decay into other, more stable elements-known as daughter isotopes-in a predictable manner, and in a precise amount of time called a half-life. Isotopes are variations of an element differentiated by the number of neutrons in their nuclei. Radiometric dating requires an understanding of isotopes. Using radiometric dating techniques, it became possible to determine the actual age of a sample. This method is called radiometric dating, and it involves the decay, or breakdown, of radioactive elements. As advances in chemistry, geology, and physics continued, scientists found a method by which the absolute age-an actual number of years-of a rock or mineral sample could be determined. Nonetheless, even though this technique did not give scientists the precise number they were looking for, it did suggest that Earth was most likely billions of years old, and not just millions as was previously thought. However, stratigraphy yields no exact age for those layers or events. Layers can be rearranged, bent, or contain inconsistencies. This technique can reveal which layers are older or which events happened before others if the layers of sediment have remained in sequential order. Stratigraphy compares the configuration of layers of rock or sediment in order to determine how old each layer is in relation to one another. Scientists also tried to use relative dating techniques to determine the age of the planet. While his estimate was wrong by a significant margin, his technique of drawing conclusions based on observations and calculations was an accurate scientific method. Lord Kelvin based his conclusion on a calculation of how long it would have taken Earth to cool if it had begun as a molten mass. While that is an enormous span of time, even an age of 400 million years would make the planet quite young in relation to the rest of the universe. In 1862, a famous Irish physicist and mathematician, Lord Kelvin, estimated that Earth was between 20-million and 400-million years old. In the 1800s, as scientists sought to determine the age of the planet, they made a few missteps. But how did scientists determine that age? The answer is complicated: It involves everything from observation to complicated mathematics to understanding the elements that make up our planet. Scientists have calculated the age of our planet to be approximately 4.5 billion years. Even more impressive, by some people’s standards, is the age of Earth. Towering mountains, deep oceans, vast continents, and sprawling glaciers-they make Earth what it is today. Take a look at a globe or a map of the world and you may be impressed by what you see.
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