Category Science

How varied is the biodiversity of Ukraine?

Ukraine is rich in animal and plant life. About 350 species of birds and more than a hundred species of mammals live there. Add to this more than 200 species of fish, too. There are fearsome predators like wolves, foxes, wildcats, and martens and hoofed animals like roe deer, wild pigs, elk and mouflons. There are also several species of rodents like hamsters, jerboas, field mice etc. Among birds, the major species are the black and hazel grouse, owls, gulls and partridges. Migrating birds are also found in abundance, like wild geese, ducks and storks. About 385 species of wild life are listed as endangered in the Red Book of Ukraine.

As for natural vegetation, Ukraine has three main zones – Polissya (woodland and marsh), the forest-steppe and the steppe. The Polissya zone, in the northwest and north, has one quarter of it with mixed woods like oak, elm, birch, hornbeam, ash, maple, pine linden, alder, poplar, willow and beech. The forest-steppe lie south of the Polissya and only one-eighth of this zone has forests. Further south is the steppe zone which is mostly composed of treeless plains used for cultivation.

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WHAT WAS THE MERCURY SEVEN MISSION?

On May 15, 1963, the last mission of Project Mercury got under way. Astronaut Gordon Cooper closed out things in style as his flight stretched the capabilities of the Mercury spacecraft to its limits.

The Mercury Seven, also referred to as the Original Seven, were a group of seven astronauts selected to fly spacecraft for Project Mercury – the first human space flight program by the U.S. Even though there were some hiccups, the project, initiated in 1958, was largely successful in its three goals of operating a human spacecraft. investigating an astronaut’s ability to work in space, and recovering spacecraft and crew safely.

Youngest of the Mercury Seven

The final flight of Project Mercury took place in May 1963. The youngest of the Original Seven, astronaut Gordon Cooper, went on to become the first American to fly in space for more than a day during this mission.

Leroy Gordon Cooper Jr. was born in 1927 and served in the Marine Corps in 1945 and 1946. He was commissioned in the U.S. Army after attending the University of Hawaii.

He was called to active duty in 1949 and completed pilot training in the U.S. Air Force. He was a fighter pilot in Germany from 1950 to 1954 and earned a bachelor’s degree at the Air Force Institute of Technology in 1956. He served as a test pilot at Edwards Air Force Base in California until he was selected as an astronaut for Project Mercury. Cooper flew Mercury-Atlas 9, the last Mercury mission, which was launched on May 15, 1963. He called his capsule Faith 7, the number indicating his status as one of the Original Seven astronauts.

Conducts 11 experiments

Longer than all of the previous Mercury missions combined. Cooper had enough time in his hands to conduct 11 experiments. These included monitoring radiation levels, tracking a strobe beacon that flashed intermittently, and taking photographs of the Earth.

When Cooper sent back black-and-white television images back to the control centre during his 17th orbit, it was the first TV transmission from an American crewed spacecraft. And even though there were plans for Cooper to sleep as much as eight hours, he only managed to sleep sporadically during portions of the flight. After 19 orbits without a hitch, a faulty sensor wrongly indicated that the spacecraft was beginning re-entry. A short circuit then damaged the automatic stabilisation and control system two orbits later. Despite these malfunctions and the rising carbon dioxide levels in his cabin and spacesuit. Cooper executed a perfect manual re-entry.

Lands without incident Cooper had clocked 34 hours and 20 minutes in space, orbiting the Earth 22 times and covering most of the globe in the process. This meant that he could practically land anywhere in the globe, a potential pain point that the U.S. State

Department was nervous about. In fact, on May 1, 1963, the country’s Deputy Under Secretary fuel, venting gas that made the spacecraft roll, and more in what felt like a never-ending series during their eight-day mission. They, however, completed 122 orbits, travelling over 5.3 million km in 190 hours and 56 minutes, before safely making their way back to Earth.

After accumulating more than 225 hours in space, Cooper served as the backup command pilot of Gemini 12, which was launched in November 1966, and the backup command pilot for Apollo 10 in May 1969. By the time Cooper left NASA and retired from the Air Force in July 1970, human beings had set foot on the moon, further vindicating the Mercury and Gemini projects that Cooper had been involved with.

Picture Credit : Google 

WHAT IS CONSIDERED A HEATWAVE?

India was reeling under a searing heatwave recently, with the mercury soaring past the 45-degree mark in some places. But what is a heatwave? What causes it? What are the dos and don’t when a heatwave is expected? Let’s find out.

What is a heatwave?

A heatwave is a period of excessively hot weather, which may be accompanied by high humidity, especially in tropical countries such as ours. It is measured relative to the usual weather in a particular region and relative to normal temperatures there for the season.

A heatwave occurs when a system of high atmospheric pressure enters an area and remains there for two days or more. In such a system, air from the upper levels of our atmosphere is pulled downwards towards the ground where it becomes compressed and increases in temperature.

When is a heatwave declared?

A heatwave is declared when an area records a maximum temperature of 40 degrees Celsius and at least 4.5 notches above normal temperature for two consecutive days. A severe heatwave is declared when the maximum temperature crosses 47 degrees Celsius, according to the Indian Meteorological Department. The IMD began keeping temperature records 122 years ago. Amid a 71% rain deficit, India saw its warmest March in 2022. As of May 1, 2022, Bikaner in Rajasthan was the hottest place with 47.1 degrees Celsius, according to the IMD.

Colour-coded warnings

The IMD issues colour-coded warnings – green, yellow, orange, and red – depending on the severity of the weather condition, with red being the extremest, to alert the authorities concerned. Green means there’s no unusual change in the weather, while yellow suggests authorities should be prepared as hot weather lasting days is likely. A ‘red’ warning is issued for a severe heatwave, while an ‘orange’ warning is issued for a heatwave. A ‘red’ warning is issued to caution people not to step out between 1 p.m. and 5 p.m.

Severe heatwaves could lead to loss of lives, power outages on account of increased use of air-conditioning, wildfires, and crop failure, among other things.

Dos and don’ts

In extreme heat conditions, there is a high likelihood of people of all age groups suffering a heat stroke or dehydration. Stay indoors at least till 6 in the evening and drink plenty of water and buttermilk to stay hydrated.

As for don’ts, do not expose yourself to direct sunlight between 11.30 a.m. and 3.30 p.m. as heatwaves are likely to be at their peak during this time. Do not go to open terraces to play till at least 5 in the evening and do not leave children or pets in parked vehicles. Avoid strenuous activities when outside in the afternoon.

Last but not least, do not ignore symptoms such as excessive thirst, unusual fatigue, dizziness, throbbing headache, lack of sweating despite the heat, and muscle cramps, and seek immediate medical help.

Picture Credit : Google 

WHICH IS THE LARGEST LIZARD IN THE WORLD?

The Komodo dragon is the largest living lizard in the world. These wild dragons typically weigh about 154 pounds (70 kilograms), but the largest verified specimen reached a length of 10.3 feet (3.13 meters) and weighed 366 pounds (166 kilograms).

Komodo dragons are large lizards with long tails, strong and agile necks, and sturdy limbs. Their tongues are yellow and forked. Adults are an almost-uniform stone color with distinct, large scales, while juveniles may display a more vibrant color and pattern.

The muscles of the Komodo’s jaws and throat allow it to swallow huge chunks of meat with astonishing rapidity. Several movable joints, such as the intramandibular hinge opens the lower jaw unusually wide. The stomach expands easily, enabling an adult to consume up to 80 percent of its own body weight in a single meal, which most likely explains some exaggerated claims for immense weights in captured individuals. When threatened, Komodos can throw up the contents of their stomachs to lessen their weight in order to flee.

Although males tend to grow larger and bulkier than females, no obvious morphological differences mark the sexes. One subtle clue does exist: a slight difference in the arrangement of scales just in front of the cloaca. Sexing Komodos remains a challenge for human researchers; the dragons themselves appear to have little trouble figuring out who is who.

Komodo dragons eat almost any kind of meat, scavenging for carcasses or stalking animals that range in size from small rodents to large water buffalo. Young feed primarily on small lizards and insects, as well as snakes and birds. If they live to be 5 years old, they move onto larger prey, such as rodents, monkeys, goats, wild boars and deer (the most popular meal). These reptiles are tertiary predators at the top of their food chain and are also cannibalistic.

Although the Komodo dragon can briefly reach speeds of 10 to 13 mph (16 to 20 kph), its hunting strategy is based on stealth and power. It can spend hours in one spot along a game trail — waiting for a deer or other sizable and nutritious prey to cross its path — before launching an attack.

Most of the monitor’s attempts at bringing down prey are unsuccessful. However, if it is able to bite its prey, bacteria and venom in its saliva will kill the prey within a few days. After the animal dies, which can take up to four days, the Komodo uses its powerful sense of smell to locate the body. A kill is often shared between many Komodo dragons.

Monitors can see objects as far away as 985 feet (300 meters), so vision does play a role in hunting, especially as their eyes are better at picking up movement than at discerning stationary objects. Their retinas possess only cones, so they may be able to distinguish color but have poor vision in dim light. They have a much smaller hearing range than humans and, as a result, cannot hear sounds like low-pitched voices or high-pitched screams.

The Komodo dragon’s sense of smell is its primary food detector. It uses its long, yellow, forked tongue to sample the air. It then moves the forked tip of its tongue to the roof of its mouth, where it makes contact with the Jacobson’s organs. These chemical analyzers “smell” prey, such as a deer, by recognizing airborne molecules. If the concentration of molecules present on the left tip of the tongue is greater than that sample from the right, the Komodo dragon knows that the deer is approaching from the left.

This system, along with an undulatory walk, in which the head swings from side to side, helps the dragon sense the existence and direction of food. At times, these reptiles can smell carrion, or rotting flesh, up to 2.5 miles (4 kilometers) away.

This lizard’s large, curved and serrated teeth are its deadliest weapon, tearing flesh with efficiency. The tooth serrations hold bits of meat from its most recent meal, and this protein-rich residue supports large numbers of bacteria. Some 50 different bacterial strains, at least seven of which are highly septic, have been found in the saliva. Researchers have also documented a venom gland in the dragon’s lower jaw. In addition to the harmful bacteria, the venom prevents the blood from clotting, which causes massive blood loss and induces shock.

The Komodo’s bite may be deadly, but not to another Komodo dragon. Those wounded while sparring with each other appear to be unaffected by the bacteria and venom. Scientists are searching for antibodies in Komodo dragon blood that may be responsible.

The lizard’s throat and neck muscles allow it to rapidly swallow huge chunks of meat. Several movable joints, such as the intramandibular hinge, open its lower jaw unusually wide. The dragon’s stomach also easily expands, enabling an adult to consume up to 80 percent of its own body weight in a single meal. When threatened, Komodo dragons can throw up the contents of their stomachs to lessen their weight in order to flee.

Komodo dragons are efficient eaters, leaving behind only about 12 percent of their prey. They eat bones, hooves and sections of hide, as well as intestines (after swinging them to dislodge their contents).

At the Smithsonian’s National Zoo, the Komodo dragon eats rodents, chicks and rabbits. Occasionally, he consumes fish and carcass meals of beef.

Credit : National  zoo Smithsonian education 

Picture Credit : Google

WHAT IS GRAVITATIONAL SINGULARITY?

A gravitational singularity, spacetime singularity or simply singularity is a condition in which gravity is so intense that spacetime itself breaks down catastrophically. As such, a singularity is by definition no longer part of the regular spacetime and cannot be determined by “where” or “when”. Trying to find a complete and precise definition of singularities in the theory of general relativity, the current best theory of gravity, remains a difficult problem. A singularity in general relativity can be defined by the scalar invariant curvature becoming infinite or, better, by a geodesic being incomplete.

Gravitational singularities are mainly considered in the context of general relativity, where density apparently becomes infinite at the center of a black hole, and within astrophysics and cosmology as the earliest state of the universe during the Big Bang/White Hole. Physicists are undecided whether the prediction of singularities means that they actually exist (or existed at the start of the Big Bang), or that current knowledge is insufficient to describe what happens at such extreme densities.

General relativity predicts that any object collapsing beyond a certain point (for stars this is the Schwarzschild radius) would form a black hole, inside which a singularity (covered by an event horizon) would be formed. The Penrose–Hawking singularity theorems define a singularity to have geodesics that cannot be extended in a smooth manner. The termination of such a geodesic is considered to be the singularity.

The initial state of the universe, at the beginning of the Big Bang, is also predicted by modern theories to have been a singularity. In this case, the universe did not collapse into a black hole, because currently-known calculations and density limits for gravitational collapse are usually based upon objects of relatively constant size, such as stars, and do not necessarily apply in the same way to rapidly expanding space such as the Big Bang. Neither general relativity nor quantum mechanics can currently describe the earliest moments of the Big Bang, but in general, quantum mechanics does not permit particles to inhabit a space smaller than their wavelengths.

Credit : Wikipedia 

Picture Credit : Google 

WHAT ARE THE FOUR FUNDAMENTAL FORCES OF NATURE?

The Four Fundamental Forces of Nature are Gravitational force, Weak Nuclear force, Electromagnetic force and Strong Nuclear force. The Four Fundamental Forces of Nature are Gravitational force, Weak Nuclear force, Electromagnetic force and Strong Nuclear force.

Gravitational Force

The gravitational force is weak but very long-ranged. Furthermore, it is always attractive. It acts between any two pieces of matter in the Universe since mass is its source.

Weak Nuclear Force

The weak force is responsible for radioactive decay and neutrino interactions. It has a very short range and. As its name indicates, it is very weak. The weak force causes Beta-decay ie. the conversion of a neutron into a proton, an electron and an antineutrino.

Electromagnetic Force

The electromagnetic force causes electric and magnetic effects such as the repulsion between like electrical charges or the interaction of bar magnets. It is long-ranged but much weaker than the strong force. It can be attractive or repulsive and acts only between pieces of matter carrying an electrical charge. Electricity, magnetism, and light are all produced by this force.

Strong Nuclear Force

The strong interaction is very strong but very short-ranged. It is responsible for holding the nuclei of atoms together. It is basically attractive but can be effectively repulsive in some circumstances. The strong force is ‘carried’ by particles called gluons; that is, when two particles interact through the strong force, they do so by exchanging gluons. Thus, the quarks inside of the protons and neutrons are bound together by the exchange of the strong nuclear force.

Note:  While they are close together the quarks experience little force, but as they separate the force between them grows rapidly, pulling them back together. To separate two quarks completely would require far more energy than any possible particle accelerator could provide.

Credit : Clearias

Picture Credit : Google