Hoor Asrar describes a curious natural phenomenon of Tectonic plates and Turkish earthquake
Earth’s Tectonic plates and Turkish earthquake have moved continuously since they emerged a whopping 3.6 billion years ago. Interestingly, previously, it was perceived that these plates formed anywhere from 3.5 billion to 3 billion years ago and another research has even estimated that the plates are 3.7 billion years old. Through a detailed process it was discovered the onset date of plate tectonics by analyzing ancient zircon crystals from Western Australia. Some of the zircons date to 4.3 billion years ago, meaning they existed when Earth was a mere 200 million years old that is described as just a baby in geological terms.
The recent movement of the tectonic plates resulted in an extremely devastating earthquake that killed tens of thousands of people and scores more injured that struck south-eastern Turkey, near the Syrian border. The earthquake, which hit near the town of Gaziantep, was closely followed by numerous aftershocks – including one quake which was almost as large as the first. It was reported that the first earthquake was big – it registered as 7.8, classified as major on the official magnitude scale. It broke along about 100km of fault line, causing serious damage to buildings near the fault. There were many aftershocks following the current earthquake and scientists are expecting it to follow the same trend as the previous big one in the region.
Earthquakes are measured on Richter scale and the number attributed to an earthquake represents a combination of the distance the fault line has moved and the force that moved it. A tremor of 2.5 or less usually cannot be felt, but can be detected by instruments. The Turkish earthquake at 7.8 is classified as major and usually causes serious damage, as it has in this instance.
Extremely Heavy Tectonic Plates And Turkish Earthquake
The Earth’s crust is made up of separate bits, called plates that nestle alongside each other. These tectonic plates and Turkish earthquake often try to move but are prevented by the friction of rubbing up against an adjoining one. But sometimes the pressure builds until one plate suddenly jerks across, causing the surface to move. In this case it was the Arabian plate moving northwards and grinding against the Anatolian plate. Friction from the plates has been responsible for very damaging earthquakes in the past.
In respect of this earthquake it was mentioned that the extremely heavy jolts experienced by the affected areas were among the deadliest earthquakes in any given year, only two in the last 10 years have been of equivalent magnitude and four in the previous 10 years. Ironically it was pointed out that this was a region where there had not been a major earthquake for more than 200 years or any warning signs, so the level of preparedness would be less than for a region which was more used to dealing with tremors.
In this context, researchers used these zircons, as well as younger ones dating to 3 billion years ago, to decipher the planet’s ongoing chemical record. They were involved in reconstructing how the Earth changed from a molten ball of rock and metal to that is seen in existence now. Plate tectonics refers to how humongous slabs of solid rock glide over Earth’s mantle, the layer just below the crust. These continental slabs shift, fracture and collide, causing earthquakes to occur, mountains to grow and oceans to form. Besides Earth, no other known planetary bodies have plate tectonics and it is likely that Earth has life because of plate tectonics.
In this matter it is mentioned that over time rocks capture carbon dioxide, a greenhouse gas that helps to warm Earth although too much CO2 can lead to global warming and plate tectonics ensures that these rocks eventually get dragged down and melted and their CO2 is spewed out as gas through volcanoes, Live Science previously reported. Without this process, Earth might freeze.
However, because the earliest plate tectonics have been covered up and recycled over the geological eons, determining its age can be challenging. To investigate, a host of researchers collected 15 grapefruit-size rocks and pulverised them into their smallest mineral components, forming sand. Luckily, zircons appeared dense, so it was easy to separate them from the rest of the sand by using a method akin to gold panning.
Next, the researchers took the zircons — more than 3,500 in all — and zapped them with a laser to measure their chemical makeup using mass spectrometry. The team also determined each zircon’s age by measuring its uranium content, a radioactive element with a known rate of decay, which enables scientists to determine how long each sample has existed.
However, only 200 of these zircons were considered fit for study meaning they had retained their chemical properties from billions of years ago. It was also mentioned that unlocking the secrets held within these minerals is no easy task as the researchers analysed thousands of these crystals to come up with a handful of useful data points but each sample has the potential to tell us something completely new and reshape how we understand the origins of the Earth. The researchers also looked at each zircon’s aluminum content. Research on modern zircons has shown that high-aluminum zircons form in just a few ways.
Ancient Zircons Clues Offers
So, the presence of aluminum in ancient zircons offers clues about how they were produced and what was going on at that time, geologically speaking. After analysing the 200 zircons, each the width of just a few human hairs, the researchers found a marked increase in aluminum concentrations about 3.6 billion years ago.
This compositional shift probably marks the beginning of plate tectonics and potentially could signal the emergence of life on Earth but what needs doing is to do lot more research to determine this geologic shift’s connections to the origins of life. The team linked high-aluminum zircons with the onset of plate tectonics because one of the ways these unique zircons form is when rocks deep beneath Earth’s surface melt.
It is really hard to get aluminum into zircons because of their chemical bonds and for it pretty extreme geologic conditions are required. In case of rocks were melting deep beneath Earth’s surface, then Earth’s crust, the outermost layer of Earth, was likely getting thicker and beginning to cool and this thickening was likely part of the transition that led to the movement of the plates.
An earlier study on rocks from the 4 billion-year-old also indicated that Earth’s crust was thickening around this time. Most credible fact is that now these locations are separated by thousands of miles but they are telling a pretty consistent story, which is that around 3.6 billion years ago something globally significant was happening.
The next stage is to look for traces of ancient life in the Australian zircons with a view to hunt for other extremely old zircons to see whether they give similar results about Earth’s crust thickening around 3.6 billion years ago. The Weekender