Category Science & Technology

What do scientists actually do?

The scientists throughout the world are hard at work. Some are studying atoms and molecules. Others are making discoveries about chemicals, liquids, heat, light, motion, or sound.

Physical scientists learn about how things work in the world and in outer space. They study all matter that is not alive, from tiny atoms to stars and planets.

Scientists work in every field imaginable, and can therefore be found working for an expansive range of employers. Large and small companies will hire scientists to work on products and research projects. Universities will hire scientists to do research work or to teach. Governments and hospitals issue research grants and hire scientists to work on funded projects. Regardless of the path the scientist decides to follow, the ultimate goal is to always add knowledge and insight to the larger scientific community, as well as to help ignite new discoveries for the future.

Picture Credit : Google

What do chemists do?

Chemists. One of the physical sciences is chemistry. Chemists study chemicals and other materials to find out what they are made of. They also learn how these things change when they join with other substances. Chemists take molecules apart and put them together in new ways. They try to find out how chemicals can be used to make things people need, such as fuels, medicines, plastics, and thousands of other materials. Some chemists study how light, heat, and other forms of energy change chemical substances.

A chemist will often work as part of a larger research team in order to create much needed compounds for use in a wide variety of practical applications. A chemist also works to improve the quality of established chemical products and utilizes advanced computer programs to establish new technologies in the field.

Almost every industry benefits from the theories and chemical compounds brought about by research in the chemical sciences.

Picture Credit : Google

All about element No. 85

At any given point of time, there is only about 25 g of astatine that occurs naturally on our planet. If that doesn’t wow you, then it’ll help to nudge you along by mentioning that that is less than two tablespoons of naturally occurring astatine on Earth at any given instant!

When there is so little of something around, it surely is difficult to find it – even when its existence has been revealed. For astatine, it was the periodic table of elements created by Russian chemist Dmitri Mendeleev in 1869 that predicted its existence. It would be over 70 years later that the element is first successfully discovered.

Properties predicted

Mendeleev’s periodic table predicted properties of what was then an unknown element. It was to fill in the blank space left for element number 85 on the periodic table. Positioned right below iodine in the halogen group, Mendeleev called it eka-iodine.

Among the first claims for the discovery of this element came in November 1931. A physicist with controversial methods, American Fred Allison at the Alabama Polytechnic Institute said that he found the element. He even called it alabamine (after Alabama), but as his results couldn’t be replicated and his equipment and methods were shown to be faulty, his claim bit the dust.

Breakout of WWII

Two groups next came close to discovering the element in mineral samples in the 1930s. Horia Hulubei and Yvetter Cauchois were researchers at the Sorbonne in Paris and they used a high-resolution X-ray apparatus to analyse mineral samples. They believed they detected the as-yet-undiscovered element, but World War II put paid to their research.

The other group to suffer a similar fate was headed by Swiss chemist Walter Minder. After observing the radioactivity of radium, Minder suggested that it appeared to have another element present. The chemical tests that he undertook suggested properties like iodine for the element, but he was never able to categorically make a claim.

Produced, finally!

The first recognised discovery of astatine finally came about in 1940. It wasn’t identified in nature, but instead was successfully produced at the University of California Berkeley by researchers Dale R. Coson, Kenneth Ross Mackenzie and Emilio Segre.

Using a particle accelerator, this group of scientists bombarded bismuth with alpha particles to produce an isotope of astatine. Noting that the element produced was both highly radioactive and unstable, they named it astatine – derived from the Greek word astatos meaning unstable.

Even though they reported their discovery, they weren’t able to continue their research much further. This was owing to the demands of World War II, which diverted all the resources devoted to the study of radioactive materials towards the making of nuclear weapons.

Found in nature

Astatine was found in nature for the first time a few years later by Austrian physicist Berta Karlik and her assistant Traude Bernert. While the war was still raging, Karlik was able to identify astatine as an intermediate in radioactive decay chains.

With news not flowing freely during the war, Karlik was under the impression that they were the first to discover element number 85, and they even reported their results along with a name for the element. When made aware of the results from the Berkeley group, Karlik continued to study astatine and was able to expand on the subject of decay chains that form the element.

Astatine, with the symbol At, is the heaviest-known halogen, and is also the least reactive and most metallic within the halogen group. Decades have now passed since astatine was finally discovered, but the element continues to be steeped in mystery. With the longest-known isotope having a half-life of eight hours and only tiny amounts of the element ever produced, studying the element hasn’t been easy.

 

Picture Credit : Google

What things can’t China manufacture yet still today?

There are two areas of advanced industrial processes that China still fails to master:

Chip Making and Jet Turbine Blades.

Indeed there are several Chinese-designed Chips, yet to produce them you need one of these:

It can easily be argued that this is the most advanced piece of machinery in the world. To function it combines laser, radio and EUV optics, semiconductors, robotics, advanced material engineering, industrial chemistry, applied quantum physics.

While Chinese companies are indeed able to engineer their chip-sets, to manufacture them to the last standards they have to lease the technology from European or American companies. Chinese made machines are still about two generations back.

The Chinese aviation industry is indeed making great progress, yet it is nowhere near to be able to manufacture one of these: which in turn means that their jet engines are at least 20 years behind current GE or Rolls-Royce engines. Indeed China has yet to be able to manufacture a single reliable passenger jet despite purchasing Western Engines and avionics, as the Comac C919 project is still riddled with issues.

Once China masters these processes we can definitely state that the “catch-up” phase is complete.

 

Credit : Quora

Picture Credit : Google

What is the purpose of Rudram-1 missile?

RudraM-1 is India’s first indigenous anti-radiation missile. It was successfully flight tested on October 9 by the Defence Research and Development Organisation (DRDO), which developed it. Once it is ready for induction. RudraM-1 will part of the tactical weaponry of the Indian Air Force. The new generation anti-radiation missile with a speed of Mach 2 (twice the speed of sound) is likely to be integrated into the IAFS Sukhoi fighter jets.

Purpose of an anti-radiation missile

An anti-radiation missile is a missile designed for use against enemy radars on the ground. Besides detecting these missiles can target radiation-emission sources, jammers (devices used to disrupt signals from reaching) and radios used for communication and Surveillance. Mainly used in the initial part of an air conflict to strike at the air defence systems of the enemy, they can play a crucial role in disrupting jamming platforms and destroying radars, thereby clearing the way for fighter jets to launch attacks. It is also said that the missiles can prevent own systems from getting jammed.

Bang on target

According to the DRDO, RudraM-1, launched from a Su-30 MKI fighter jet, hit the radiation target located on the Wheeler Island off the coast of Odisha with pinpoint accuracy. The target seeking air-to-surface missile has a strike range of 250 km and can be launched from heights of 500 metres to 15 km.

Its navigation mechanism comprises an Inertial Navigation System (a computerised mechanism) and a Global Positioning System, which is satellite-based. Armed with a guidance system called Passive Homing Head, which can detect, classify and engage targets, RudraM-1 can detect radio emissions 100 km away. Once the missile locks onto the radiation target it is capable of hitting it accurately even if the enemy switches off the radar midway.

 

Picture Credit : Google

What is the mystery of centaurs?

Is it an asteroid? Is it a planet? Is it a comet? If there is a solar system object that neither gives a resounding yes nor a certain no to these questions, then chances are that they belong to a class of celestial objects called centaurs. While estimates for the number of centaurs in the solar system are now placed anywhere above 44,000, they still remain mysterious with secrets to be revealed.

Despite their current count being in the thousands, we have been aware of their existence for less than half-a-century. And it all started in 1977, when Chiron, the first-identified member in what was then a new class of objects, was discovered.

Blink and you miss it

American astronomer Charles Kowal, who had already discovered one of the moons of Jupiter, was searching for peculiar objects in the solar system. Working at the Hale Observatories in California, the U.S., Kowal photographed the skies with telescopes and then examined them on a blink comparator – the device that had enabled American astronomer Clyde Tombaugh to discover Pluto in 1930.

The blink comparator holds two photographic plates and alternates them rapidly. While stars, which are fixed, remain steady as the plates alternate, any moving object – be it a comet, planet or asteroid – appears to jump from one plate to another. Using photographic plates of the sky in the constellation Aries on October 18 and 19, 1977, Kowal was able to discover Chiron on November 1.

How to classify

While media organisations were ready to call it the most distant asteroid discovered or even the 10th planet (Pluto was still classified as a planet in 1977), the astronomers realised that they had a question in their hands as classification wasn’t proving to be straightforward. It eventually became the first centaur, named after the half-human, half-horse being in Greek mythology, a new class of objects.

Chiron was named after the centaur Chiron in Greek mythology, believed to be the wisest and most just among all centaurs. The names of other centaurs in mythology were to be reserved for other objects that were to fall into this type.

The first centaur to be discovered, in fact, was 944 Hidalgo in 1920. It wasn’t until 2060 Chiron was discovered that astronomers realised that these belonged to a distinct group unlike any other in the solar system. Chiron, too, has been identified in images going back to 1895 following its discovery, which enabled us to determine its orbit more accurately.

Many things at once

Centaurs are now known to be a little bit of everything – asteroids, planets and comets. Small solar system bodies orbiting the sun between the outer planets, they usually have unstable orbits and are too small to be observed. Most centaurs inhabit the complex, dynamic region between Jupiter and Neptune.

Observations of 10199 Chariklo, the largest confirmed centaur so far, have revealed that it has a system of rings, akin to the ones popularly associated with Saturn, and also seen with Jupiter, Uranus and Neptune. There is a possibility that Chiron too has rings like Chariklo.

While the rings enable centaurs to draw parallels with planets, their colour and composition gives them a different identity. Most of them are either reddish or blue to blue gray in colour. We now know that the blue and blue gray centaurs are dark objects like comets and ones that are red are more like asteroids, having an organic surface.

Blue centaurs are composed of ice and are covered by a layer of dust, much like comets. This, along with highly elliptical orbits, suggests that some centaurs either are, or could become, comets.

Astronomers and astronomical organisations worldwide are involved in both classifying and cataloguing centaurs, whose numbers have been ever-increasing since they were identified to be a separate class of objects. These centaurs, like their namesake, are for now seen to be many things at the same time. They might, however, well be holding clues to some of the questions regarding our solar system for which we are still searching for answers.

 

Picture Credit : Google