The "why" of discovery might be more in the philosophical than the scientific realm; it's safe to assume in general terms that curiosity is a big motivating force behind discovery. In one sense, the reason behind black holes' discovery may have been somewhat indirect or even unintended; they appeared in solutions to Einstein's field equations from General Relativity, which is basically the theory of gravity that has proved to be most consistent with observation. Subsequently, other scientists stepped forward with mathematical solutions that described a consistent theoretical framework for their existence; thereafter, the hunt for observational evidence began. Study of radiation from Cygnus X-1 is generally believed to place it as the first black hole identified.
Note that quasars, now generally accepted as being powered by supermassive black holes, were discovered about a dozen years earlier, but their significance in relation to black holes not really understood and accepted until almost a decade after the compelling evidence from Cygnus.
Stephen Hawking helped develop the field of theoretical physics and cosmology by working on the concept of black holes, the theory of general relativity, and the nature of the universe's origins and evolution. He also made significant contributions to the study of quantum mechanics and the search for a unified theory that could explain all physical phenomena.
Stephen Hawking's work on black holes has advanced our understanding of fundamental physics, leading to discoveries about the behavior of black holes and the nature of the universe. This knowledge has contributed to technological advancements and new insights into the fundamental laws of physics, which could have practical applications in the future. Additionally, Hawking's work inspires curiosity and innovation in scientific research and education worldwide.
As defined by a patent "The Theory of Super Relativity is a proposed Theory of Everything that extends Albert Einsteins Relativity Theory. It is based on the Classical physics concept of a Tensor Field which describes space as a variable geometric quantity. All material objects are made from this object which is space itself, and force is mediated by this object.
Yes, black holes do, indeed, exist in the universe. We've actually "seen" them, but they can be observed only indirectly. No light can escape them and all nearby matter gets trapped in their gravitational field. Particles which are not far enough away to escape but not close enough to be pulled in are accelerated around the black hole at immense speeds in an accretion disk. The compression and heating of these materials at the event horizon results in the emission of X-ray radiation, which can be detected by orbital X-ray satellites like Chandra. It is also possible to detect a black hole with optical telescopes by spotting what is called gravitational lensing.The first black hole discovered, Cygnus X-1, was "seen" in the late 1900's. Our galaxy is believed to have several million black holes in it, and they come in various sizes. These include super-massive black holes like Sagittarius A, which is the one at the center of the Milky Way. We'll also see intermediate and stellar black holes, and possibly micro black holes as well. Use the link below to learn more.There are quite a few, but far beneath the earth.(did that help or do you think i am really not paying attention to your question)Yes.Yes. black holes have been detected in nature.Which is to say, objects have been detected whose properties are such that no other phenomena could account for them. you can't "see" them for obvious reasons.I linked some sites that you can go to, they have info and lists and pictures of the known blackholes.
The discoveries of Stephen Hawkings (and lots of other scientists) help us get a better understanding of how the Universe works. It is not always clear in advance what benefits we get from such an understanding, but if you look at the past, an understanding of the Universe has helped us quite a lot.
Stephen Hawking helped develop the field of theoretical physics and cosmology by working on the concept of black holes, the theory of general relativity, and the nature of the universe's origins and evolution. He also made significant contributions to the study of quantum mechanics and the search for a unified theory that could explain all physical phenomena.
Yes, Einstein developed the Theory of Relativity on his own, using his own intellectual capacities and insights. He worked on his theory while employed as a patent clerk in Switzerland, independently formulating the groundbreaking ideas that revolutionized the field of physics.
The theory of relativity can help you but not with the equation E=mc^2 E=mc^2 is just a conversion between mass and energy.
Well he didn't exactly invent it or even discover it but he did develop the theory of relativity to help us all understand it.
Stephen Hawking's work on black holes has advanced our understanding of fundamental physics, leading to discoveries about the behavior of black holes and the nature of the universe. This knowledge has contributed to technological advancements and new insights into the fundamental laws of physics, which could have practical applications in the future. Additionally, Hawking's work inspires curiosity and innovation in scientific research and education worldwide.
holes are no help
Albert Einstein's theory of relativity is used in various ways today, including in GPS technology, where the time dilation effects predicted by the theory need to be accounted for to ensure accurate navigation. Einstein's insights also play a crucial role in astrophysics, where they help scientists understand phenomena such as black holes and gravitational waves. Additionally, his theory continues to inspire research in fundamental physics and our understanding of the universe.
Albert Einstein developed the theory of relativity, which consists of two major branches: special relativity and general relativity. His equation E=mc^2 showed the relationship between mass and energy, laying the foundation for the development of atomic energy and nuclear weapons.
He invented atomic power He came up with the theory of Relativity. He came up with the theory of Gravity. He had all these equations like E=mc2
The concept of SR units, or spacetime units, is a fundamental aspect of special relativity theory. In special relativity, space and time are combined into a single four-dimensional spacetime continuum. SR units help measure distances and intervals in this spacetime, accounting for the effects of time dilation and length contraction at high speeds. This concept is crucial for understanding how objects and events are perceived differently depending on their relative motion, as predicted by special relativity theory.
Yes, while Albert Einstein developed his theory of relativity independently, he was influenced and inspired by the work of other scientists such as Isaac Newton, James Clerk Maxwell, and Hendrik Lorentz. However, the theory of relativity is primarily credited to Einstein.
As defined by a patent "The Theory of Super Relativity is a proposed Theory of Everything that extends Albert Einsteins Relativity Theory. It is based on the Classical physics concept of a Tensor Field which describes space as a variable geometric quantity. All material objects are made from this object which is space itself, and force is mediated by this object.