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7: Geologic Time

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    The geologic time scale and basic outline of Earth’s history were worked out long before we had any scientific means of assigning ages in years to events of Earth history. Working out Earth’s history depended on realizing some key principles of relative time. Nicolaus Steno (1638-1686) introduced basic principles of stratigraphy, the study of layered rocks, in 1669 [1]. William Smith (1769-1839), working with the strata of English coal mines, noticed that strata and their sequence were consistent throughout the region. Eventually, he produced the first national geologic map of Britain [2]. Nineteenth-century scientists developed a time scale using Steno’s principles, showing the order in which many rock units formed. Using this time scale, geologists can place all events of Earth history in order without ever knowing their numerical ages.

    It shows a man
    Figure \(\PageIndex{1}\): Nicolas Steno, c. 1670

    • 7.1: Relative Dating
      Relative dating is the process of determining if one rock or geologic event is older or younger than another, without knowing their specific ages—i.e., how many years ago the object was formed. The principles of relative time are simple but were not generally accepted by scholars until the scientific revolution of the 17th and 18th centuries.
    • 7.2: Absolute Dating
      Relative dating allows scientists to tell the story of Earth events, but does not provide specific numeric ages, and thus, the rate at which geologic processes operate. Absolute dating utilizes various techniques that allow geologists to give rock formations, sediment deposits, faults, etc. a numerical age.
    • 7.3: Fossils
      Fossils are any evidence of past life preserved in rocks. They may be actual remains of body parts (rare), impressions of soft body parts, casts and molds of body parts (more common), body parts replaced by mineral (common), or evidence of animal behavior such as footprints and burrows. The body parts of living organisms range from the hard bones and shells of animals, soft cellulose of plants, soft bodies of jellyfish, down to single cells of bacteria and algae.
    • 7.4: Correlation and the Geologic Time Scale
      Correlation is the process of establishing which sedimentary strata are of the same age but geographically separated. Correlation can be determined by using things like rock types, unique rock sequences, or index fossils. There are four main types of correlation: stratigraphic, lithostratigraphic, chronostratigraphic, and biostratigraphic.

    Thumbnail: Perhaps no place on Earth better exemplifies the principles geologists use to determine the ages of rocks than Arizona’s Grand Canyon National Park.

    This page titled 7: Geologic Time is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Chris Johnson, Matthew D. Affolter, Paul Inkenbrandt, & Cam Mosher (OpenGeology) via source content that was edited to the style and standards of the LibreTexts platform.