Presentation on theme: "Geologic Time. 01: Geologic Time Scale Huge sections of time are broken down into smaller groups of time: Eons, Eras, Periods, and Epochs Eon is the."— Presentation transcript:
01: Geologic Time Scale
Huge sections of time are broken down into smaller groups of time: Eons, Eras, Periods, and Epochs Eon is the largest time block (kind of like what we would think of as years). Era is a little less time (like months) Period would be shorter time (like weeks) Epochs are even shorter (like days) (**No different then when we take years and divide them into months, weeks, and days.)
(next after the 1 st period)
(later – this is the time of the dinosaur)
Lesson 2 Relative and Absolute Time
Fossils Fossils are rocks that formed from the remnants (whats left) of once- living things. All living organisms, under the right conditions, can be fossilized. Mold Freezing Petrification Crystallization
An imprint of something that was once living. When something is filled with sediment (rocks) and makes it look 3-D.
When something is filled with atoms of rock material; this makes them very hard (rock). *Commonly found with wood.
When a living organism gets stuck in something sticky (like sap) the sap and the organism harden and get preserved. An organism gets frozen and the super cold temps prevent it from decaying; therefore preserving it.
The remains of an organism's activities but not of the organism itself. EXAMPLES: -broken eggshells from a dinosaur's nest are trace fossils. - footprints from an organism -chewed section of a plant -coprolites fossilized dung or feces (meaning: poop)
There are two types of dating which geologists can use to make the timelines: relative dating and absolute dating. Relative dating does not give an exact age (in years) to rocks or geologic events…
Instead, relative dating puts the events in sequential order; the oldest comes first, and all the rest of the events follow after, on therelative dating timeline. Example of relative dating (putting events in sequential order):
Since there werent scientists around during the formation of the Earth (or for any of the geologic history of Earth) they (scientists) need to rely on carefully recorded observations, so they can make assumptions about these things. These types of assumptions are called principles, and in these cases, observations made by the scientific community, over time, have repeatedly supported the assumptions. Geologic Assumptions: 1. Uniformitarianism 2. The Principle of Superposition 3. The Principle of Original Horizontality 4. The Principle of Faunal Succession
By studying the rocks on Earth, geologists (people who study rocks) can make a chart that outlines the geologic periods of time when rocks were formed.
Uniformitarianism What is it? The belief that all of the processes (things) that are shaping the Earth today were the same processes (things) at work in the past; (also that these processes occurred at the same rate and in the same way as they do today). What can they assume with this? Geologists can study how fast a process is occurring today, (like formation of sedimentary rock layers or erosion), and make then they can make assumptions about how the processes occurred in the past. Doing this can help them form relative time lines for past events.
The Principle of Superposition What is this one? In layers of rock that have been undisturbed, (or as geologists say, "un-deformed,) the lowest layers formed first, then the next, and the next, and so on up to the top layer. What can they assume with this? That the oldest layer is on the bottom and the layers get younger and younger as you go up.
The Principle of Original Horizontality Using this principle, (plus knowing that movements of the crust can bend, fold, twist, break, and move rock layers) we can assume that if we see several layers of rocks that are in any form other than horizontal, they must have been acted upon by a disturbance of the crust of some kind. This tells us that when sedimentary rock layers are first formed, the sediments fall in horizontal layers.
The Principle of Faunal Succession With this principle we focus on the fossils found in rock layers. If we can estimate the age of the fossils, we can make assumptions about the age of the sedimentary rock layer in which the fossil is found.
The Law of Cross-Cutting Relationships: An igneous rock intrusion is younger than the rocks into which it has intruded. The Law of Unconformity: An unconformity is a place where some of the existing rock layers have been eroded by water or wind or changed in some way causing pieces to be missing. The Law of Deformity: A deformity may be a tilting, faulting, or folding of existing rock layers. Therefore, for the rock layers to be deformed, they must be older than the event that deformed them.
An igneous intrusion is younger than the rocks into which it has intruded (goes through). An unconformity is a place where some of the existing rock layers have been eroded by water or wind (Hint: if wind is hitting it what layer would it be?)
More advanced dating techniques have allowed geologists to get more exact dates. Absolute dating is the: The measurement of time in definite periods of time and is measured with something that gives us a definite (exact) time. It assigns specific dates to rocks and geologic events. SO…
Radiometric dating: Radioactive decay starts with only parent element (an unstable isotope). Because it's unstable, it will decay into a stable daughter element. The time it takes for half of the amount of parent element to decay is constant, (and known as half-life). After one half-life, half of the material is the parent element and the other half is more stable daughter element. After another half life, one-fourth will be the parent element. As the substance keeps decaying, the amount of parent element will shrink, although it will never be completely gone. The substance would then mostly consist of the daughter element. All rocks contain radioactive material that decays over time. The rate of radioactive decay allows scientists to establish the absolute age of a rock. ** the most common radioactive element is carbon-14 found in all living organisms.
Lesson 3 Origin and Evolution of Life
Scientists learn about Earths geological (the Earth itself) and biological (living things) history through evidence from rocks and fossils. A fossil record helps us to understand the past and why things are the way they are today.
Theory of evolution Life on Earth did not always look the same as it does today. Life has evolved (changed / altered). Evolution explains how new species of organisms arise or how existing organisms adapt to new conditions over time. DinosaurModern day bird
An adaptation refers to a characteristic of an organism that allows it to survive in a particular environment. When an adaptation ( a change ) makes an organism more likely to survive and reproduce, the organism may pass the new adaptation on to its offspring ( babies ); organisms with the new adaptation will produce more babies than organisms that dont have the new adaptation. This process called: natural selection is why some organisms with certain adaptations survive and others do not, depending on Earth's changing conditions.
Chemical evolution: The idea that the appearance of living systems (stuff) on Earth from non-living molecules.
Phylogeny is studying how different organisms (plants/animals/etc.) are connected (related) through evolution (change over time). We use something called acladogram to show (in an image/diagram) how one organism is related to another one. Living fossils: Creatures that are very similar to species that lived long ago (without much change) are called living fossils.