Black Holes The term black hole was first used in 1969 by the American scientist John Wheeler to describe an object that had such a huge gravitational pull that not even light could escape it, thereby rendering it invisible or black. John Michell extended upon this idea in a paper called the "Philosophical Transactions of the Royal Society of London" in which he pointed out that a star that was sufficiently massive and compact would have such a strong gravitational pull that not even light could escape it as any light emitted by the star would be pulled back in by gravity - this was the first theory of a black hole. It is known today that black holes are in fact the fate of huge stars. When these huge stars collapse they eventually collapse to a point where they are infinitely dense yet infinitely small - a black hole. Inside a star, hydrogen atoms are constantly being fused to make helium atoms. This process is known as nuclear fusion, nuclear fusion produces energy in the forms of light and heat, the outward pressure that is created by this outpouring of energy is normally enough to counteract the gravity that is constantly trying to squeeze the star ever smaller. Soon the star runs out of hydrogen to burn and so begins to burn heavier elements (such as oxygen and lithium), when this happens the star will grow up to 100 times its original size. But eventually the stars supply of fuel will run out and the star will no... ... middle of paper ... ...s a black hole. First, as you neared the even horizon, time would appear to take longer and longer and as you entered the even horizon your image would remain there for an eternity. This is because at that very moment, the light that you are emitting would be caught in the event horizon. It would appear to an observer that you were frozen in time, staying in the same position forever. But in fact it is just the light, not you that is stuck. As you entered the black hole time would go faster and faster, and if you looked up you would be able to see the entire universe evolving in front of you. But this amazing sight comes at a great cost, as you begin to near the singularity you would feel your body begin to stretch. Eventually your body would be stretched so far by the colossal gravity that you would be ripped apart!
The origins of the super-massive black holes which concludes how they were formed and what caused them to form is an unsolved problem which is yet a mystery of astrophysics. ( Millis 2014)
Geologist John Mitchell is credited with first devising the idea of a black hole. He said that if some force could compress the sun down to an small enough size, it would have a gravitational field so strong, that one would need to be going faster than the speed of light to escape it (UTFC). All objects in the universe have what is called a schwarzschild radius. An object’s schwarzschild radius is the radius that an object would have to be compressed into in order to have an escape velocity greater than that of the speed of light, or a black hole. (VSBH).
Until recently, theorists believed that wormholes could exist for only an instant of time, and anyone trying to pass through would run into a singularity. But Khalili shows the reader that more recent calculations show that a truly advanced civilization might be able to make wormholes work. By using something physicists call “exotic matter,” which has a negative energy, the civilization could prevent a wormhole from collapsing on itself. Perhaps someday in the far future, wormholes will become a useful asset in universal transportation.
...ke for instance the two images below. The first is a two-dimensional representation of the gravity of a normal star. Imagine any object floating through space as a marble. Said marble rolling along the flat surface of the space will roll into the indentation made by the sun's gravity. If you flick the marble hard enough, it can roll out of the indentation and roll away. The second pic is a representation of the gravity made by a black hole. Notice that if the marble rolls into the hole, there's no way it can get out, since there is no end to the hole.
The idea of Black Holes was first proposed in the 1700s by scientists John Michell and Pierre-Simon Laplace, who argued, independant of each other, that there might be objects in the universe with such a large gravitational force, that even light could be trapped. Published in 1916 Einstein’s theory of general relativity which included how gravity does affect light’s motion, gave way to scientific discoveries involving black holes. In Einstein’s own theory, he was only able to approximate the solutions to some of his own equations, however Karl Schwarzschild was able to provide the solutions. These solutions described objects like black holes that had such massive density that nothing could escape them. Schwarzschild theorized that if an object had such a small radius, that the escape velocity will be greater than the speed of light. Because as previously mentioned, nothing is faster than the speed of light, the object would be sucked into itself by it’s own gravitational pull, which would cause the object to disappear. What r...
You would have most recently seen and heard of black hole in Christopher Nolan’s hit movie Interstellar, and felt like a nasty bouncer above the head? Well, there is a simple explanation to what black holes are and how do they exist.
... hole. The opening of a black hole is called the event horizon. And once something goes inside, it is trapped forever inside of it. Light, matter and other things cannot escape. The radius of each event horizon is called the Schwarzschild radius, named after Karl Schwarzschild the person who led to the theory of black holes A black hole is when there is a strong gravitational pull and there was a time delayed. The whole light not being able to escape thing seems pretty complicated. why? Because when you think about it, light not being able to escape the black hole doesn't seem too realistic. Black holes are created from an overdensity of a star collapsing in on itself. That overdensity is what creates the whole black hole part, the concept of the black hole sucking things in and possibly destroying them without a trace, that is the part that makes it seem weird.
Every day we look into the night sky, wondering and dreaming what lies beyond our galaxy. Within our galaxy alone, there are millions upon millions of stars. This may be why it interests us to learn about all that we cannot see. Humans have known the existence of stars since they have had eyes, and see them as white glowing specks in the sky. The mystery lies beyond the white glowing specks we see but, in the things we cannot see in the night sky such as black holes.
By 1936, astronomers had realized that the hazy balls they sometimes saw in their telescopes, which looked like stars obscured by gas, were actually galaxies (Hibbison).
a term most of us have probably heard. This idea is known as Newton's Universal Law of Gravity. This idea
The Effects of Gravity There are some people who worry when they're outside, if they don't keep a good grip on the ground, they'll just go flinging off into space. They needn't really worry. about this, because gravity generally keeps that sort of thing from happening. The thing is, no one is really sure what causes gravity, but the effects have been studied by many. physicists and astronomers of the world.
Einstein himself, working at Princeton with Nathan Rosen had discovered that the equations of relativity actually represent a black hole as a bridge between two regions of flat space-time, a phenomenon known as the “Einstein-Rosen Bridge”. Later on, in 1963, the New Zealand mathematician Roy Kerr found that if a black hole is rotating, a singularity still forms, but in the form of a ring, not a point. It was believed that in principle, a particle may be able to fall towards the singularity, but if at some point moved through the hole instead of the ring, the particle may not be lost forever. Therefore, with these theories in mind, a particle falling into a black hole will fall through the ring that the singularity has become, then going through the Einstein-Rosen Bridge, eventually being spewed out of the white hole into another space-time continuum.
To start out, I want to put to rest a common myth about black holes. One that I was often told about as a child was that they are like a cosmic vacuum going around sucking up any and everything in it’s path. This is not true, but if an objects orbit should take its self close enough to the event horizon of a black hole then it would be unable to get out because of the intense gravitational pull. The origin of the name black hole comes from the idea that a black hole is a one way deal,...
Initially, Albert Einstein was the person to predict the existence of black holes through his General Theory of Relativity, in which he had created several general equations that show the interaction of gravitation as a result of space being curved by matter or energy. In 1915, he published Einstein’s field equations, which specify how the geometry of space and time is influenced by whatever matter and radiation are present, and form the core of Einstein's general theory of relativity (Redd). The general theory relativity was the initial step in the process to finding out more information about black holes. As time went on, there were a few main contributors that solved these equations to help develop better theories on black holes. One of the most important contributors to the development of a better u...
The gravitational force at the surface of the planet is the force that binds all bodies to earth, this force is one of the four forces recognized by physicists, and this kind of force is known as "gravity" it attracts every celestial object to earth, and though it is the most important of the forces essential for our lives, it is the least comprehended of them all Throughout ages scientists have tried to solve the mystery of gravity, and one of the first discoveries concerning gravity was made by Aristotle who concluded from his experiments that the downward movement of any body is that has weight had a proportional relationship between its quickness in motion and its size. However this theory was accepted for centuries, but after a series of experiments made by Galileo, Aristotle's theory was proved to be incorrect, as Galileo said after a series of experimenting at the Pisa tower that bodies of different sizes fall with the same speed. Later on, the idea that the force is needed so as to change the motion of the body was discovered. After that a great scientist was to improve all the previously accepted theories, this scientist was Newton who was to make decisive advances in understanding gravity. In his first law Newton said that a body in state of rest or uniform motion in a straight line will keep on moving unless acted upon by a force, while in his second Newton expressed his first law in a more quantitative way as he said that force acting on a body is the rate of change of it's momentum which can be put in a rule as F= ma Where (F) is the force acting on the body while (a) and (m) are the acceleration and inertial mass of the body respectively. Newton also made the law of gravitation in which he expressed the gravitational force of attraction between any two bodies acting along the line joining them as Where (m) is the mass of the two bodies and (r) is the distance between them, while (G) is the proportionality constant known as the constant of gravitation, afterwards Newton made his very important assumption in which he showed that the inertial mass of a body is identical to its gravitational mass which implied that the gravitational force exerted on or by an object is directly proportional to its inertia.