Methods of Dating the Earth Part 1: Relative Dating

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All the way at the beginning of this geology  series, we talked about Earth’s history and  

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the geological timescale spanning  4.5 billion years of Earthly events,  

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from the Hadean eon to the Phanerozoic eon  we are still living in today. But how is it  

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that geologists determine the age of the  Earth and its different rock formations? 

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There are two methods of dating rocks. These  are relative dating, which qualitatively  

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compares the age of formations based on their  stratigraphic sequence, and absolute dating,  

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or radiometric dating, which uses the decay of  radioisotopes to calculate a rock’s precise age.  

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Before the advent of radiometric dating in the  early 1900s, geologists assigned relative dates  

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to different layers in an outcrop based on  the inferred sequence of their deposition,  

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or emplacement, which they would then compare to  other outcrops using distinctive formations called  

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marker beds. In fact, most sedimentary rocks  are dated using relative dating since they do  

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not meet the criteria for radiometric dating,  which we will discuss in the next tutorial. 

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Let’s now discuss some of the principles that  geologists use when determining relative ages. The  

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principle of original horizontality states that  sediments accumulate in horizontal layers called  

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beds, though some sand layers that are deposited  as dunes may be inclined as much as 35 degrees.  

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This is called crossbedding. In  cross bedded sedimentary rocks,  

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the sediment is deposited in sets at the angle  of repose on the lee side of dunes and ripples,  

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which explains their inclination. In addition,  only sand-sized sediment can form cross beds.  

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Say for example that you find an outcrop with  a horizontally layered siltstone on top of a  

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vertically layered siltstone. When you apply the  principle of original horizontality, you realize  

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that there was a large time gap between deposition  of the horizontal and vertical formations.  

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The principle of superposition states that,  unless tectonic forces have overturned the  

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outcrop, beds on the bottom are  usually older than beds on top.  

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The principle of cross-cutting relationships  states that any geological feature which cuts  

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across a rock must be younger than the feature  it disrupts. So, if an igneous intrusion is found  

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cutting through a sandstone, the intrusion must  be younger than the sandstone it cuts through.  

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The principle of inclusions states that any  rock fragments that are a part of a larger  

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formation must be older than the formation they  are a part of. For example, lithic fragments,  

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which are pieces of a preexisting rock, are common  types of grains in sedimentary rocks; so if you  

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find a clast of schist in a sandstone, the schist  must be older than the sandstone it is a part of.  

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The principle of faunal succession states that  there is a historical order in which organisms  

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evolved over time, and that certain specific  fossils can be used to determine a rock’s age.  

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Organisms that only existed for a short period  of Earth’s history are most useful for this,  

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and their fossils are called index fossils.  For example, if you find a trilobite fossil  

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in a bed, then it must have been deposited  between the Cambrian and Permian Periods. 

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Another useful concept for qualitatively dating  rocks is that of “missing time”, or gaps in the  

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rock record called unconformities. There are  four types of unconformities: a nonconformity,  

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an angular unconformity, a disconformity, and a  paraconformity, all of which represent missing  

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time. But what exactly is meant by missing time?  Recall the Wilson cycle from a previous tutorial,  

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and the ways that geologic environments change  over time. For example, during one period an area  

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may be a part of a sedimentary basin, but then  get uplifted 100 million years later during an  

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orogeny, transforming the once sedimentary  environment into an erosional environment,  

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and then, after another 100 million years, it  could once again become a sedimentary basin.  

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Let’s consider what the rock record would look  like here. Sedimentary rocks would be deposited  

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during the first period, which would later  get eroded during uplift, removing some amount  

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of the sedimentary record, which would later  be capped by sediments from the last period.  

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The rocks that were eroded during  uplift represent missing time,  

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and the gap between the two sedimentary  layers is called an unconformity. 

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Let’s rigorously define the types of  unconformities. A disconformity is an erosional  

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boundary between two beds of sedimentary rock, as  in the example we just discussed. A paraconformity  

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is also a boundary between two beds of sedimentary  rocks, but is not erosional and simply represents  

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a period of nondeposition. They represent less  missing time than a disconformity. A nonconformity  

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is a boundary between an older non-sedimentary  rock, like an igneous or metamorphic rock,  

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and younger sedimentary rock layered on top. And  an angular unconformity is a boundary between  

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tectonically tilted layers of sedimentary  rocks and overlying horizontal strata. 

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So, that covers the principles that geologists use  to assign relative dates to Earth’s rock layers,  

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and some of the challenges that  this method poses. As we mentioned,  

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prior to the development of radiometric dating,  this was all that geologists were able to do.  

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But radiometric dating is a powerful technique,  so let’s move forward and learn about that next.