My Science School

After taking an arts course at University College, London, he enrolled in the faculty of medical science in October 1848. A brilliant student, he was graduated a bachelor of medicine with honours in 1852; in the same year he became a fellow of the Royal College of Surgeons and house surgeon at University College Hospital. A visit to Edinburgh in the fall of 1853 led to Lister’s appointment as assistant to James Syme, the greatest surgical teacher of his day, and in October 1856 he was appointed surgeon to the Edinburgh Royal Infirmary. In April he had married Syme’s eldest daughter. Lister, a deeply religious man, joined the Scottish Episcopal Church. The marriage, although childless, was a happy one, his wife entering fully into Lister’s professional life.

When three years later the Regius Professorship of Surgery at Glasgow University fell vacant, Lister was elected from seven applicants. In August 1861 he was appointed surgeon to the Glasgow Royal Infirmary, where he was in charge of wards in the new surgical block. The managers hoped that hospital disease (now known as operative sepsis—infection of the blood by disease-producing microorganisms) would be greatly decreased in their new building. The hope proved vain, however. Lister reported that, in his Male Accident Ward, between 45 and 50 percent of his amputation cases died from sepsis between 1861 and 1865.

In this ward Lister began his experiments with antisepsis. Much of his earlier published work had dealt with the mechanism of coagulation of the blood and role of the blood vessels in the first stages of inflammation. Both researches depended upon the microscope and were directly connected with the healing of wounds. Lister had already tried out methods to encourage clean healing and had formed theories to account for the prevalence of sepsis. Discarding the popular concept of miasma—direct infection by bad air—he postulated that sepsis might be caused by a pollen-like dust. There is no evidence that he believed this dust to be living matter, but he had come close to the truth. It is therefore all the more surprising that he became acquainted with the work of the bacteriologist Louis Pasteur only in 1865.

Pasteur had arrived at his theory that microorganisms cause fermentation and disease by experiments on fermentation and putrefaction. Lister’s education and his familiarity with the microscope, the process of fermentation, and the natural phenomena of inflammation and coagulation of the blood impelled him to accept Pasteur’s theory as the full revelation of a half-suspected truth. At the start he believed the germs were carried solely by the air. This incorrect opinion proved useful, for it obliged him to adopt the only feasible method of surgically clean treatment. In his attempt to interpose an antiseptic barrier between the wound and the air, he protected the site of operation from infection by the surgeon’s hands and instruments. He found an effective antiseptic in carbolic acid, which had already been used as a means of cleansing foul-smelling sewers and had been empirically advised as a wound dressing in 1863. Lister first successfully used his new method on August 12, 1865; in March 1867 he published a series of cases. The results were dramatic. Between 1865 and 1869, surgical mortality fell from 45 to 15 percent in his Male Accident Ward.

In 1869, Lister succeeded Syme in the chair of Clinical Surgery at Edinburgh. There followed the seven happiest years of his life when, largely as the result of German experiments with antisepsis during the Franco-German War, his clinics were crowded with visitors and eager students. In 1875 Lister made a triumphal tour of the leading surgical centres in Germany. The next year he visited America but was received with little enthusiasm except in Boston and New York City.

Credit : Britannica 

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Joseph Lister was a British medical scientist and a pioneer in preventive medicine. He was the founder of antiseptic medicine, which helped prevent infection during and after surgery. His antisepsis principles laid the foundation of modern infection control Joseph Lister was born in 1827 in Essex, now in London, into a prosperous family. His father Joseph Jackson Lister was a wine merchant and an amateur physicist and microscopist. His discovery led to the modern achromatic microscope.

Soon after graduating in medicine in 1852, Lister became a fellow of the Royal College of Surgeons and house surgeon at University College Hospital in London. In 1861, he was appointed surgeon to the Glasgow Royal Infirmary, where he was in charge of wards in the surgical block. At that time, wound infections were a common occurrence that frequently killed patients. Doctors did not then realise that patients were dying of operative sepsis, an infection of the blood by disease-producing microorganisms. Between 1861 and 1865 alone, Lister noted that about 50% of his amputation cases died (from sepsis).

Eureka moment

Lister’s moment of realisation came when he read about Louis Pasteur’s research onputrefaction. He realised that the process behind fermentation might also be involved with wound infection. In his ward, Lister began his experiments with antisepsis. He found an effective antiseptic in carbolic acid, which had already been used as a means of cleansing sewers and had been empirically advised as a wound dressing in 1863. This proved extremely effective at preventing sepsis and gangrene. Lister first successfully used his new method in 1865, and in 1867, published a series of cases. The sepsis cases in his ward came down drastically. His recommendations met with some resistance in the medical profession, but eventually came to revolutionise surgery.

Many firsts

Lister also has many firsts to his credit. He was the first person to isolate bacteria in pure culture (Bacillus lactis) using liquid cultures containing either Pasteur’s solution. Lister also pioneered the use of catgut and rubber tubing for wound drainage. He also showed that urine could be kept sterile after boiling in swan-necked flasks.

In 1883 Queen Victoria made him a Baronet, of Park Crescent in the Parish of St Marylebone in the County of Middlesex. He was appointed one of the 12 original members of the Order of Merit in 1902. Lister is one of the two surgeons in the United Kingdom who have the honour of having a public monument in London. Lister's stands in Portland Place.

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What you need

A glass bottle

Food colour

Modelling day Drinking straw

A small op

A sketch pen

What to do:

1. Plug the mouth of the glass bottle with the modelling day

2. Insert the straws into the clay and then pull it out leaving a straw sized hole in the clay. Make sure you clear out the clay caught in the straw.

3. In the cup, mix a little water with a few drops of food colouring.

 4. Dip the straw into the water. Then dose the top end with your thumb so that a drop of water enters the straw

5. Make the straw horizontal and release your thumb, letting the water drop ride back towards your hand when it is somewhere in the centre of the straw re-plug the top with your thumb.

6. Keep the plug with your thumb constant as you push the straw through the hole in the modelling day. Squeeze the day until you have a seal around the straw. Then release your thumb.

7. Place the bottle on a stable surface. Mark the initial position of the drop on the straw with a sketch pen.

8. Now, hold the bottle in both hands while it rests on the table. Observe the drop.

9. Let go of the bottle and let it stand on the table.

What happens :

When you hold the bottle, you see the water drop slowly crawl up the straw. When the bottle is left on its own, the water drop Moves down again. Why?

The bottle is full of air. In fact that is why the drop does not simply slide down the straw when you plug it into the clay seal. The air holds the drop up in the straw.

When you hold the bottle, your body heat warms it up. This causes the air inside the bottle to warm up as well. And warmer air expands. This causes the water drop to move up as the expanding air looks for a way out.

When you let go of the bottle, it cools down gradually. The cooling air contracts and the water drop down again.

You can try this experiment by putting the glass bottle in a hot water basin and then a cold water basin, you want to see drastic changes in the position of the water droplet.

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What you need:

A staple remover (the clawed kind) A sturdy file or folder

Sticky tape

Scissors

A plastic spoon

 A small ball of foil

What to do:

1. Stick the staple remover (the broader side) to the top of the folder using glue or sticky tape. The staple remover should be firm and steady once stuck

2. Next place the stem of the spoon against the top of the staple remover and tape it. The spoon should rest steadily against the length of the staple remover and its end should line up with the end of the staple removers top.

3. Place the roll of foil in the spoon.

 4. Gently pull the head of the spoon down and let go.

What happens:

The ball of foil flies off the catapult you made.

Why?

The catapult is a combination of several simple things. First comes the lever, which is the simplest form of a machine. A lever is a bar resting on a support. One end of the lever usually holds the load while the other end is used to apply pressure to move that load. The support on which the lever rests is known as the fulcrum. It is the fulcrum which makes it easy to transfer force from one end of the lever to another which allows the load to

In our case, there are two levers held together by a spring. The first lever is the staple remover its fulcrum is the end that is opposite the claws where the joint is.

The second lever is the spoon. Its fulcrum is the part that is stuck to the staple remover.

Both these levers are joined by a spring that's inside the staple remover. This spring is what allows the spoon to snap back up when released and throw the ball of foil.

You can place a book inside the folder which forms the base. This will allow you to change the angle of the catapult. You can find out how that affects your throw.

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What you need:

A Ziploc bag

A big heavy book

A straw

Modeling clay

What to do:

1. Open the zip of the Ziploc bag just a bit and insert one end of the straw into it

 2. Using the modelling clay. Seal the bag around the straw. That way the zip is closed and the straw is sealed in. No air can enter or leave the bag except through the straw.

3. Now, place the bag under the book in such a way that the straw inside it should hang off the edge of the table that the bag is resting on

4. Blow hard through the straw.

What happens?

 The bag inflates and the book is lifted off the table!

Why?

When you blow air into the bag, you are pushing air in and compressing it. This compressed air pushes against the bag which in turn pushes against the book, lifting it up.

This is also how tyres on our bicycles work. They are filled with compressed air that can take our entire weight!

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What you need:

A balloon

A fluorescent lamp or fluorescent the light

 What to do:

1. Inflate the balloon and knot in mouth closed

2. Dim the lights of the room.

 3. Rub the inflated balloon vigorously over your hair or on a woollen sweater

4 Touch the balloon to the two metal electrodes at the end of the tube

What happens:

When the balloon is touching the metal prongs, the tube lights up for a few moments.

Why?

This happens due to static electricity. Static means stationary. When you rub two objects against each other (like the balloon and your hair), they develop stationary electrical charges .To understand why this happens. We have to go to the microscopic level. Everything in our world is made up of tiny particles called 'atoms.

These atoms are, in turn, made up of even smaller particles known as electrons, protons and neutrons. The protons and neutrons remain inside the atom but the electrons like to use any excuse to jump in and out of the atom. When you rub two objects together, the electrons from one object jump to the other. This exchange of electrons is what is termed as electrical charge.

When the balloon is rubbed over hair, electrons jump from our hair to the balloon and stay there.

A fluorescent tube light is usually coated on the inside with a white material (known as a phosphor) and is filled with mercury gas.

When you plug in the fluorescent tube, an electric current is passed through it. Electricity is nothing but the movement of electrons. These electrons dash through the mercury gas, causing it to emit ultraviolet light.

Ultraviolet light is able to the human. That's where the phosphor coating comes in. This coating absorbs ultraviolet light and releases visible light instead.

When you hold the charged balloon dose to the metal prongs of the light the electrons jump from the balloon to the tube (since metal is a good conductor), causing it to light up. This light remains until all the electrons at the point of contact (where the balloon meets the prongs) are used up.

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A selection of notable finds from the past year

CANADA: Analysis of wood samples from the Norse settlement at L'Anse aux Meadows in New foundland, shows that Vikings occupied the Americas as early as 1021 - exactly 1,000 years ago. This is the earliest known record of humans crossing from Europe to the New World

FRANCE: A freshly-unearthed Bronze Age stone known as the Saint-Belec Slab, may be the oldest 3D map in Europe. Archaeologists believe the patterns engraved on the 4,000-year-old slab depict an area of western Brittany

EGYPT: The discovery of a 3,000-year-old city near Luxor known as Aten-is hailed as one of the most important finds since Tutankhamun's tomb. The "lost golden city" was founded by Tutankhamun's grandfather Amenhotep III (1391-1353 BC), one of ancient Egypt's most powerful rulers

U.S.: Radiocarbon dating of fossilized footprints found in New Mexico show that people were living in North America more than 20,000 years ago - about 5,000 years earlier than previously thought. The previous theory was that ice sheets had prevented human migration to the region during the ice age

LEBANON: The remains of at least 25 solider killed defending Christian-held Sidon during the Crusades, are uncovered in the moat of the Saint Louis Castle. This is one of only two archaeologically documented mass burials of Crusaders

MOROCCO: Artefacts unearthed in a cave in Morocco, dating back 120,000 years, indicate that humans used bone tools to render animal skins for fur and leather. The discovery provides the oldest-known evidence for clothing in the archaeological record

SAUDI ARABIA: A series of camel sculptures carved into rock faces are believed to be the oldest large-scale animal reliefs in the world. A fresh study puts the camels at between 7,000 and 8,000 years old older than Stonehenge (5,000 years old) or the Pyramids at Giza (4,500 years old).

TIBET: A pattern of hand and footprints made by children more than 220,000 years ago is the oldest artwork ever found. The youngsters, probably Neanderthals or members of the related Denisovan species, pressed their hands and feet into soft limestone, which later hardened.

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The everglades national park in the U.S. is home to one of the largest wetlands in the world. But there’s an invasive species there has been singularly decimating native mammal species for decades.

It's the largest!

The largest subtropical wilderness in the U.S., Everglades National Park is located on the southern part of Florida. Covering an area of more than 6,000 sq.km. the region is a veritable mosaic of ecosystems from freshwater sloughs, prairies, and pineland to cypress, mangrove, coastal lowlands, marine, and estuarine. More than 40 species of mammals, nearly 50 species of reptiles, over 300 species of birds and an equal number of fish species, in addition to several types of insects such as butterflies, arachnids, millipedes, and centipedes, call the Park home. The region is a refuge for several rare, endangered, and threatened species. Within the limits of the Park are breeding grounds for several waders. It is also a significant corridor for migratory birds. The Park was listed as a UNESCO World Heritage Site in 1979. However, it was moved to the List of World Heritage in Danger in 1993 and remained so till 2007. In 2010, the region was included in the list again and has continued to remain there. This is because the Park, "due to its low lying elevation, is vulnerable to rising sea levels driven by a warming climate".

Wildlife

The birds found in the Park include ducks, teals, pintails, wigeons, shovelers, gadwalls, geese, storks, ibises, herons, egrets, bitterns, spoonbills, eiders, hummingbirds, swifts, nighthawks, sandpipers, plovers, gulls, snipers, stilts, terms, godwits, curlews, doves, kingfishers, cuckoos, hawks, kites, falcons, kestrels, loons, coots, rails, moorhens, mynahs, sparrows, finches, thrushes, wrens, crows, warblers, Flycatchers, crows, grosbeaks, swallows, orioles, buntings, nuthatches, starlings, pelicans, cormorants, woodpeckers, grebes, shearwaters, parakeets, and owls. Among the amphibians living here are frogs, toads, newts, and sirens. The land and marine mammals one can sight here are manatees, panthers, deer, bobcats, raccoons, opossums, foxes, otters, and rabbits. The reptile world in the Park is dominated by alligators, crocodiles, snakes, boas, pythons, iguanas, skinks, geckos, lizards, turtles, and terrapins.

Irula expertise to rescue Florida!

Burmese pythons are among the largest snakes in the world, and can grow up to even 20 feet in length. Native to Southeast Asia, these pythons are an invasive species in Everglades. They are said to have reached the place in the 1980s when exotic pet trade thrived and many of the snakes arrived in the region as pets. When it turned out they'd grow to be over 20 feet, many of the pet owners just released them into the wild. It is said that when Hurricane Andrew unleashed its fury in the region in 1992, many captive pythons spread into the region and have thrived in the swamps since. Nobody knows the exact number of pythons out there. And that's been bad news! These snakes have been decimating native mammal species for decades. As part of the initiatives to tackle the menace, a python removal programme was introduced. A few years ago, the efforts included a team from India. To be precise, the Irula tribe snake hunters from Tamil Nadu. Why the Irulas? Because they are considered among the best snake hunters in the world. But they would be crossing continents and working in a different terrain. Would it work? Work, it did! In just 14 days, they managed to catch as many Burmese pythons.

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The denser a substance, the heavier it is for a given volume: this is why dense stones sink in water while air-filled buoys float. The fact that ice floats thus precisely means that it is less dense than liquid water. The reason is that water molecules in ice follow a geometrical structure in which the distance between two molecules is larger than their average distance in the liquid. At low temperature, when water becomes ice, the molecules move slowly enough to fit themselves into this structure.

But at higher temperature in the liquid, they move too fast to do so and often come closer to each other. As a consequence, water unusually takes more space in its solid form and ice is less dense than liquid water. You can observe that if you leave a water bottle in the freezer when the water freezes, it will need more space. Actually, it might even break the bottle, so be careful!

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Former First Lady Melania Trump recently launched a new platform which will release NFTS regularly. The first digital art piece to be sold on her platform is titled Melania's Vision

Melania's platform aims to assist children aging out of the foster care system by way of economic empowerment and access to resources needed to excel in the fields of computer science and technology.

Digital data

NFT stands for Non-fungible token. It is fuelled by block chain technology, meaning it is a unit of digital data. What makes NFTS different from bitcoins is that they are non-fungible. An NFT is unique and cannot be replaced with something else For example, a bitcoin could be traded for another bitcoin but you get the same thing - 10 bitcoins = 10 bitcoins or something worth 10 bitcoins. However if you trade an NFT, you get something that is completely different - an NFT art piece = whatever rate is paid for it.

NFTS can represent digital files such as audio. video, drawings/artwork, a piece of writing, items a video game and any other forms of creative work It can be used to commodify digital creations and fetch money for digital creators.

The first NFTS were based on the Ethereum open source blockchain and appeared around 2015 More recently, NFTS have become hugely popular with collectors and speculators having spent over 200 million dollars on NFT-based artwork in February March 2021. This, compared to 250 million dollars throughout 2020,

How does it work?

Since NFTS are digital data, artists who wish to sell their works as NFTS need to register with an NFT marketplace and then mint digital tokens by uploading and validating their information on a block chain. This can cost an artist anywhere between 40 and 200 dollars. After this, the artist can list his or her work for auction on an NFT marketplace, similar to Amazon or EBay.

What's the benefit?

A piece of digital art can be uploaded or circulated by anyone on the Internet. So what is the benefit for a collector buying an NFT? While the artworks can be reproduced or circulated by anyone, NFT gives the buyer the ownership rights to the original artwork. Like physical art, the artist can still retain the copyright and reproduction rights, but the person who has bought the NFT owns the original artwork.

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As we already know, on average, primates are more intelligent than other mammals, thanks to their larger brains among other aspects. Primates include humans too, considered the smartest of the lot. However, more and more studies are emerging to show just how intelligent non-human primates too are. Come, let's find out more about this through a recent experiment.

Baboons are very intelligent creatures and through various experiments it has been ascertained that they can "decipher elements of language, understanding words in a sequence. This is in addition to having "highly complicated social grouping structures, deep empathy for one another and adaptability to the developing world around them". So it makes sense they were used for a recent experiment on non-human primates.

French researchers worked with nearly 20 baboons raised at a primatology centre. In pairs, the primates were given the task of making the same choice when each was presented with a set of two images on touch screens. If both s in animals made the same choice, they were given a treat. The researchers discovered that in just three days, the baboons had come up with a system to and choose the same image even when they were not aware of what the other baboon had chosen, ruling out one imitating the other. Also, it was not a matter of colour-based choice because the baboons chose the same image even when they were presented with black-and-white ones.

This proved that baboons manage to develop social conventions to work together to Dice obtain a reward. Though earlier they had showed evidence of social conventions such as grooming, "this is the first to show a new behaviour appearing spontaneously in a group, without human intervention". According to the study, "for a behaviour to be considered a social convention its benefit must apply to the whole group, it must work consistently, and it must be one among several solutions". However, it remains a mystery how they do this.

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A newly discovered species of millipede has set a new world record for the greatest number of legs, with 1,306. Previously no millipede had been found with more than 750 legs.

The discovery of the millipede, 60m underground in a drill hole created for mineral exploration in Western Australia, is reported by Nature magazine.

The name of the new species - Eumillipes persephone - derives from the Greek word eu- (true), the Latin words mille (thousand) and pes (foot), and references the Greek goddess of the underworld, Persephone.

E. persephone has a long, thread-like body consisting of up to 330 flexible segments and is up to 0.95mm wide and 95.7mm long. It is eyeless, and has a cone-shaped head with antennae and a beak, and short legs.

Analysis suggests that E. persephone is distantly related to the previous record holder for the greatest number of legs - the Californian millipede species, Ill acme pennies.

The authors suggest that the large number of segments and legs may allow the millipede to generate pushing forces that enable it to move through narrow openings in the soil habitats in which they live.

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The Democratic Republic of Congo officially declared on December 16, 2021 the end of the 13th outbreak of Ebola Virus Disease which had resurfaced on October 8, 2021, in Beni in North Kivu province. What is Ebola Virus Disease? What causes it? Let's find out.

Deadly viral fever

Ebola is a life-threatening disease caused by a virus belonging to the family Filoviridae The viral haemorrhagic fever was first identified in central Africa in 1976. The 2014-2016 outbreak in West Africa was the largest Ebola outbreak ever since the virus was discovered, leading to over 11,000 deaths. The disease was named after the Ebola River in Congo, formerly Zaire, where it was originally identified.

Ebola is a zoonotic disease, meaning it spreads from animals to humans. The virus which badly affects the immune system as it spreads through the body is transmitted to people from animals such as chimpanzees, gorillas, and monkeys. It is thought that fruit bats of the Pteropodidae family are natural Ebola virus hosts. It spreads among humans through contact with the bodily fluids (blood, faeces, urine, vomit, or semen) of infected people. Ebola is called a haemorrhagic fever virus as it causes problems with how our blood dots leading to internal bleeding.

What are the symptoms?

The main symptoms of Ebola Viral Disease include fever fatigue, sore throat severe headache, muscle and joint pain loss of appetite, vomiting, bleeding and diarrhoea. The virus can be detected in blood within a few days of the manifestation of symptoms. Immediate medical attention, early intervention with rehydration, and symptomatic treatment are said to improve chances of survival.

There are vaccines for protection against Ebola. These anti-Ebola jabs have been administered to help control the spread of Ebola outbreaks in Congo.

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The Greenland ice sheet is the second largest noir of freshwater on Earth SINCE 1001, the rate of loss of ice man from the ice sheet has increased so-fold amounting to around 10% of the recent rise in global sea levels.

Basal slip

The ice flow is determined by the geological conditions in the ground beneath an ice sheet or glacier. The make-up of the Layers of rock and the temperature of the Earth's crust beneath are some of the key factors. The amount of water present in liquid form between rock and ice is also another factor as this acts as a lubricant in causing what is referred to as "basal slip", increasing the flow of ice.

The remoteness of Greenland and the fact that its ground is covered by ice almost 2.5 km in thickness creates specific problems in figuring out what is happening underneath. A research led by Swansea University in Wales has employed the noise created by Earth's movements to build up a detailed picture of the geological conditions beneath the Greenland ice sheet and the impact on ice flow.

Using Earth's noise

A permanent network of seismic monitoring stations was installed across Greenland in 2009 for a previous research. By measuring Rayleigh waves - seismic waves generated by movements like earthquakes extracted from Earth's noise, researchers were able to produce high-resolution images of the rock underneath the ice sheet.

By measuring the speed shape at duration of the wives, scientists were able to find out the material through which they are travelling through. In addition to this, the material properties of the rocks like rigidity and density, the layering of the rocks and physical properties of the surface soil were also worked out helping identify areas that are most susceptible to faster ice flow.

The researchers were able to find regions of high geothermal heat, soft sedimentary substrates beneath fast flowing outlet glaciers, and outlet glaciers particularly susceptible to basal slip. With a better understanding of the processes leading up to faster ice discharge, the researchers are also hoping to learn more about the global sea level rise.

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Scientists are preparing to drill into a volcano in Iceland in an attempt to create the world's first underground magma observatory. This ambitious project intends to dig deeper into the Earth's layers and further our knowledge about volcanic predictions and risks.

Earth's mantle consists mostly of hot magma, which flows as lava when there is a volcanic eruption. Due to the high temperatures and pressure under Earth's crust magma has remained inaccessible to scientific instruments and hence a mystery. But that's going to change now.

A team of international researchers is preparing to drill two km into the heart of a volcano the Krafla caldera in Iceland- to create the world's first underground magma observatory called the "Krafla Magma Test bed" (KMT). Let's learn all about the project in this Five Ws & One H...

WHAT is Krafla?

Krafla is a volcanic caldera in northern Iceland. A caldera is a large hollow that forms shortly after the emptying of a magma chamber in a volcanic eruption. The Krafla caldera is about 10 km in diameter with a 90 km long fissure zone.

It sports a crater lake of blue water, plumes of smoke, and sulphurous bubbling of dirt and gases. The Krafla has erupted 29 times since recorded history.

How did the KMT project come about?

Though scientific instruments have not been specifically used to reach magma earlier geothermal energy drilling operations have come into contact with magma accidentally. One of these sites is the Krafla caldera in Iceland.

In 2009, when engineers were expanding Krafla's geothermal power plant, a bore drill hit a pocket of 900-degree-Celsius magma by chance, at a depth of 2.1 km. Fortunately, there was no eruption and no one was hurt. However, lava flowed 9m up the well damaged the drilling machines.

Scientists were astonished to find that they were within reach of a magma pocket. That's when they decided to launch a project to study it up close and the result is the KMT.

When did the project begin?

The project was launched in 2014 and the first drilling is due to start in 2024. The $100-million project involves scientists and engineers from 38 research institutes and companies in 11 countries, including the U.S. Britain and France.

What are the objectives of the study?

• The project aims to conduct a long-term exploration of Krafla's magma reservoir and its surrounding hydrothermal envelope.
• By drilling through the rock-magma interface and into magma, scientists believe they can establish where and under what conditions magma beneath a volcano stored
• Scientists hope the project will lead to advances in geothermal power generation.
• They also hope to further knowledge about better predicting volcanic eruptions and risks involved.

What is geothermal energy?

Geothermal energy is the heat that comes from the sub-surface of the earth right from magma. It is a renewable resource that can be harvested for human use

Wells are dug a mile deep into underground reservoirs to access the steam and hot water there, which can then be used to generate power

Iceland produces 25% of its energy from geothermal sources. This is chiefly due to the presence of 600 hot springs and 200 volcanoes in the country.

What are the challenges of the KMT project?

Drilling in such a harsh environment is technically difficult. The materials must be able to withstand the super-heated steam's corrosion. The team has planned to develop the project in a phased manner to address these issues. However, there are also concerns about the likelihood of a volcanic explosion caused by the KMT operation.

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