1 1.2 Geological Time
While geology is focused on the physical structure and dynamic processes that are found on Earth, it also encompasses the concept of deep time. James Hutton (1726-1797), is credited with being the founder of modern geology in part due to his idea about geologic time. He postulated that the processes acting on Earth must’ve taken a very long time to make it look the way it does, and went in search of evidence to support his ideas. After arriving at Siccar Point, Scotland, by boat in early 1788, Hutton found the clear evidence he needed to demonstrate this understanding. In Figure 1.2.1, the orange line shows a contact between nearly vertical old sedimentary rocks and much younger ones that were nearly horizontal. Hutton inferred from the sharp junction between the two sets of rocks that there required a huge expanse of time in order to fold and erode the underlying rocks before the younger rocks were deposited.
“The Present is the Key to the Past”
After his experience at Siccar Point, Hutton wrote the following about the age of Earth: The result, therefore, of our present enquiry is, that we find no vestige of a beginning — no prospect of an end.[1] Of course he wasn’t exactly correct, there was a beginning and there will be an end to Earth, but what he was trying to express is that geological time is so vast that we humans, who typically live for less than a century, have no means of appreciating how much geological time there is. Hutton didn’t even try to assign an age to Earth, but we now know that it is approximately 4,570 million years old. Using the scientific notation for geological time, that is 4,570 Ma (for mega annum or “millions of years”) or 4.57 Ga (for giga annum or billions of years). More recent dates can be expressed in ka (kilo annum); for example, the last cycle of glaciation ended at approximately 11.7 ka or 11,700 years ago. This notation will be used for geological dates throughout this book.
Unfortunately, knowing how to express geological time doesn’t really help us understand or appreciate its extent. A version of the geological time scale is included as Figure 1.2.2. Unlike time scales you’ll see in other places, or even later in this book, this time scale is linear throughout its length, meaning that 50 Ma during the Cenozoic is the same thickness as 50 Ma during the Hadean—in each case about the height of the “M” in Ma. The Pleistocene glacial epoch began at about 2.6 Ma, which is equivalent to half the thickness of the thin grey line at the top of the yellow bar marked “Cenozoic.” Most other time scales have earlier parts of Earth’s history compressed so that more detail can be shown for the more recent parts. That makes it difficult to appreciate the extent of geological time.
To create some context, the Phanerozoic Eon (the last 542 million years) is named for the time during which visible (phaneros) life (zoi) is present in the geological record. In fact, large organisms—those that leave fossils visible to the naked eye—have existed for a little longer than that, first appearing around 600 Ma, or a span of just over 13% of geological time. Animals have been on land for 360 million years, or 8% of geological time. Mammals have dominated since the demise of the dinosaurs around 65 Ma, or 1.5% of geological time, and the genus Homo has existed since approximately 2.8 Ma, or 0.06% (1/1,600th) of geological time.
Geologists (and geology students) need to understand geological time. That doesn’t mean memorizing the geological time scale; instead, it means getting your mind around the concept that although most geological processes are extremely slow, very large and important things can happen if such processes continue for enough time.
For example, the Atlantic Ocean between Nova Scotia and northwestern Africa has been getting wider at a rate of about 2.5 centimeters (cm) per year. Imagine yourself taking a journey at that rate—it would be impossibly and ridiculously slow. And yet, since it started to form at around 200 Ma (just 4% of geological time), the Atlantic Ocean has grown to a width of over 5,000 kilometers (km)!
A useful mechanism for understanding geological time is to scale it all down into one year. The origin of the solar system and Earth at 4.57 Ga would be represented by January 1, and the present year would be represented by the last tiny fraction of a second on New Year’s Eve. At this scale, each day of the year represents 12.5 million years; each hour represents about 500,000 years; each minute represents 8,694 years; and each second represents 145 years.
Some significant events in Earth’s history, as expressed on this time scale, are summarized on Table 1.1.
| [Skip Table] | ||
| Event | Approximate Date | Calendar Equivalent |
|---|---|---|
| Formation of oceans and continents | 4.5 to 4.4 Ga | January |
| Evolution of the first primitive life forms | 3.8 Ga | early March |
| Formation of British Columbia’s oldest rocks | 2.0 Ga | July |
| Evolution of the first multi-celled animals | 0.6 Ga or 600 Ma | November 15 |
| Animals first crawled onto land | 360 Ma | December 1 |
| Vancouver Island reached North America and the Rocky Mountains were formed | 90 Ma | December 25 |
| Extinction of the non-avian dinosaurs | 65 Ma | December 26 |
| Beginning of the Pleistocene ice age | 2 Ma or 2000 ka | 8 p.m., December 31 |
| Retreat of the most recent glacial ice from southern Canada | 14 ka | 11:58 p.m., December 31 |
| Arrival of the first people in North America | 10 ka | 11:59 p.m., December 31 |
| Arrival of the first Europeans on the west coast of what is now the USA | 250 years ago | 2 seconds before midnight, December 31 |
***See 1.5 for Text and Media Attributions
- Hutton, J, 1788. Theory of the Earth; or an investigation of the laws observable in the composition, dissolution, and restoration of land upon the Globe. Transactions of the Royal Society of Edinburgh. ↵
The total of water evaporated from the land surface plus transpiration from plants
When the cloud droplets combine to form heavier cloud drops which can no longer "float" in the surrounding air, it can start to rain, snow, and hail... all forms of precipitation, the superhighway moving water from the sky to the Earth's surface.
precipitation that flows out over the landscape
process of evaporation that changes liquid and frozen water into water-vapor gas, which then floats up into the skies to become clouds.
The conversion between solid and gaseous phases of matter, with no intermediate liquid stage.
The largest reservoir of water on earth, containing over 96% or all Earth's water. This water is saline (saltwater).
