Geologic Time. Decoding the Age of our Planet & North Carolina

Geologic Time Decoding the Age of our Planet & North Carolina

The Geologic Time Scale Objectives Describe the geologic time scale. Distinguish among the following geologic time scale divisions: eon, era, period, and epoch. Vocabulary geologic time scale eon era period epoch

The Geologic Time Scale The Geologic Time Scale By studying the characteristics of rocks and the fossils within them, geologists can interpret the environments in which the rocks were deposited, reconstruct Earth s history, and possibly predict events or conditions in the future.

The Geologic Time Scale The Rock Record Geologists have divided the history of Earth into time units based upon the fossils contained within the rocks. The Geologic Time Scale is a record of Earth s history from its origin 4.6 billion years ago to the present. This scale allows the correlation of geologic events, environmental changes, and the development of life-forms that are preserved in the rock record.

The Rock Record The Geologic Time Scale

The Geologic Time Scale Geologic Time The oldest division of time is at the bottom of the geologic time scale. The time scale is divided into units called Eons, Eras, Periods, and Epochs. An Eon, measured in billions of years, is the longest time unit of the geologic time scale. An Era, defined by the differences in life-forms found in rock and measured in hundreds of millions to billions of years, is the second-longest span of time on the geologic time scale.

The Geologic Time Scale Geologic Time Precambrian Time, which makes up approximately 90 percent of geologic time, is divided into the Archean and Proterozoic Eons. The end of the Proterozoic, the more recent of the two, is marked by the first appearance of organisms with hard parts.

The Geologic Time Scale Geologic Time Plants and Animals Evolve During the Paleozoic Era, the oceans became full of a wide diversity of plants and animals; land plants appeared and were followed by land animals. The Mesozoic Era is known for the emergence and evolution of dinosaurs, reef-building corals, large predatory reptiles, and flowering plants and trees. During the Cenozoic Era, mammals increased both in number and diversity, human ancestors developed, and grasses and flowering plants expanded on land.

The Geologic Time Scale Geologic Time Periods of Geologic Time Periods, usually measured in terms of tens of millions of years to hundreds of millions of years, are defined by the life-forms that were abundant or became extinct during the time in which specific rocks were deposited. The Cenozoic is divided into three periods: the Paleogene, Neogene, and Quaternary. The boundaries between the periods of the Cenozoic are not marked by extinction events.

The Geologic Time Scale Geologic Time Epochs of Geologic Time Epochs are smaller divisions of geologic time and are usually measured in millions of years to tens of millions of years. The Cenozoic Periods have been further divided into epochs including the Paleocene and the Oligocene. Different groups of organisms have been used to distinguish the various epochs. Regardless of how a geologic period was defined, each unit contains specific characteristics that set it apart from the rest of geologic history.

The Geologic Time Scale Section Assessment 1. Match the following terms with their definitions. C eon A period D era B epoch A. time periods defined by the life forms that were present; usually measured in terms of tens of millions to hundreds of millions of years B. smaller divisions of time; usually measured in millions to tens of millions of years C. the longest period of time; measured in billions of years D. second longest period of time; measured in hundreds of millions to billions of years

The Geologic Time Scale Section Assessment 2. How does the geologic time scale correspond with the rock record? Moving upward on the scale, each division is younger, just as the rock layers in the rock record grow younger as you move upward.

The Geologic Time Scale Section Assessment 3. Identify whether the following statements are true or false. true Precambrian Time represents 90 percent of geologic time. false Human ancestors developed during the Paleozoic Era. false true The boundaries between the periods of the Cenozoic are marked by mass extinctions. Organisms in Precambrian Time had soft bodies with no shells or skeletons.

Relative-Age Dating of Rocks Objectives Apply the principles for determining relative age to interpret rock sequences. Describe an unconformity and how it is formed within the rock record. Vocabulary uniformitarianism original horizontality superposition cross-cutting relationships unconformity correlation

Relative-Age Dating of Rocks Relative-Age Dating of Rocks The principle of uniformitarianism states that the forces that continually change the surface features of Earth today have been occurring since Earth formed. Only the rate, intensity, and scale with which the forces occur have changed. The resulting sediments and rocks all record an environment and fossils within the rocks preserve evidence of the life-forms that lived during the time of deposition.

Relative-Age Dating of Rocks Principles for Determining Relative Age The concept of relative-age dating places the ages of rocks and the events that formed them in order, but without exact dates. This is done by comparing one event or rock layer to another.

Relative-Age Dating of Rocks Principles for Determining Relative Age Geologic Principles The principle of original horizontality states that sedimentary rocks are deposited in horizontal or nearly horizontal layers. The principle of superposition states that in an undisturbed rock sequence, the oldest rocks are at the bottom and each successive layer is younger than the layer beneath.

Principles for Determining Relative Age Geologic Principles Relative-Age Dating of Rocks The principle of crosscutting relationships states that an intrusion or a fault is younger than the rock it cuts across.

Absolute-Age Dating of Rocks Objectives Explain the several different methods used by scientists to determine absolute age. Describe how objects are dated by the use of certain radioactive elements. Explain how annual tree rings and glacial varves are used to date geologic events. Vocabulary radioactive decay radiometric dating half-life dendrochronology varve key bed

Absolute-Age Dating of Rocks Absolute-Age Dating of Rocks Absolute-age dating enables scientists to determine the actual age of a rock, fossil, or other object using the decay rate of radioactive isotopes. Radioactive substances emit nuclear particles at a constant rate regardless of any physical or environmental changes. The original radioactive element is referred to as the parent, and the new element is referred to as the daughter. As the numbers of protons and neutrons change with each nuclear emission, the element is converted to a different element.

Absolute-Age Dating of Rocks Absolute-Age Dating of Rocks Radioactive decay is the emission of radioactive particles and the resulting change into other elements over time.

Absolute-Age Dating of Rocks Use of Radioactive Isotopes In a process called radiometric dating, scientists attempt to determine the ratio of parent nuclei to daughter nuclei within a given sample of a rock or fossil to determine its absolute age. Because it often takes a long time for the entire amount of an isotope to decay, geologists use the half-life of an isotope.

Absolute-Age Dating of Rocks Use of Radioactive Isotopes Half-life is the length of time it takes for one-half of the original amount of an isotope to decay.

Absolute-Age Dating of Rocks Use of Radioactive Isotopes Carbon-14 Carbon-14 (C-14) is a radioactive isotope that is commonly used to determine the absolute age of an object, especially one that is of organic origin. C-14 is accurate for dating objects up to 75 000 years old. For the dating of a particularly old rock sample, a radioactive isotope with a longer half-life must be used.

Absolute-Age Dating of Rocks Other Ways to Determine Age Naturally occurring materials, such as trees, lake-bottom sediment, and volcanic ash can also be used to help geologists determine the age of an object or event.

Absolute-Age Dating of Rocks Other Ways to Determine Age Tree Rings The age of a tree can be determined by counting the number of annual tree rings in a cross section of the tree. The widths of tree rings are directly related to the climatic conditions during growth periods. Dendrochronology is the science of comparing annual growth rings in trees to date events and changes in past environments.

Absolute-Age Dating of Rocks Other Ways to Determine Age Seasonal Climatic Changes About 11 000 years ago, continental glaciers covered the northern part of the United States. Varves are bands of alternating light- and dark-colored sediments of sand, clay, and silt found in lakes that resulted from summer and winter runoff from glaciers. Varves from different lakes can be compared to determine the ages of glacial lake sediments from about 15 000 to 12 000 years ago.

Absolute-Age Dating of Rocks Other Ways to Determine Age Distinctive Sediment Layers When a widespread sediment layer is formed by an instantaneous or short-lived event, geologists may be able to determine the time of the event through radiometric dating. A key bed is a layer which has been dated and acts as a time marker, which can be used to correlate rock layers across large areas.

Absolute-Age Dating of Rocks Section Assessment 1. Match the following terms with their definitions. B half-life D dendrochronology A varve C key bed A. alternating light- and darkcolored sedimentary deposits in glacial lakes B. the time period until the ratio of parent-to-daughter atoms is equal C. a widespread layer that has been accurately dated D. the science of comparing annual growth rings in trees to date events and environmental changes

Absolute-Age Dating of Rocks Section Assessment 2. How old is an object of organic origin if it has 25 percent of carbon-14 remaining? Why? The object is 11 460 years old. To reach the 25 percent level, the carbon-14 has experienced 2 half-life cycles of 5730 years each.

Absolute-Age Dating of Rocks Section Assessment 3. Why would rubidium-87 with a half-life of 48.6 billion years probably not be useful in dating an object that is 100 000 years old? With such a long half-life, the ratio of parent-to-daughter atoms would be too small to measure.