Special relativity is a scientific theory describing how matter moves through time and space. When it was first published in 1905 by Albert Einstein, special relativity caused a revolution in the physics community, and made us look at the universe in a new light. Special relativity is one of the most well-confirmed physics theories of all time, and its predictions have been verified to more than twenty decimal places of accuracy.
The two basic postulates of special relativity are that the laws of physics are the same regardless of absolute velocity, and that the speed of light is constant for all observers. If you are in a closed box moving at constant velocity, special relativity predicts that no experiment you do inside the box can tell you how fast the box is moving. Likewise, the speed of light will remain the same for an observer inside the box, even if the box itself is moving at a large fraction of the speed of light.
Special relativity abandons the notions of “absolute space” and “absolute time” developed by Newton. Under special relativity, there is no such thing as a single universal time; rather, time is different for every observer. There is also no single universal measure of space; a single ruler can be longer or shorter depending on who measures it. Finally, special relativity unifies the concepts of space and time into a single four-dimensional structure called “spacetime.”
According to special relativity, if an object is moving at high speed relative to you, the object will appear to behave strangely. Its mass will increase, so that it becomes harder and harder to accelerate as it approaches the speed of light. It will appear to shrink in its direction of motion, becoming more and more distorted as it travels faster. The object's time will also become distorted; if there is a clock on the object, it will appear to tick more slowly. These effects happen to every object, but they only become noticeable once objects approach the speed of light.
Special relativity prohibits any object from traveling faster than the speed of light. If an object appears to go faster than lightspeed for one observer, it must be possible to find an observer who sees the object traveling backward in time. As an object's velocity approaches that of light, its mass and kinetic energy go to infinity. Even information may not travel faster than light, as this would allow messages to be sent backward in time as well.
anon990091 Post 6 |
It's much easier to understand Special Relativity if you just figure it out for yourself. |
anon334863 Post 5 |
Everyone assumes nothing travels faster than the speed of light. If something did, do you think you'd be able to see it? My point is that just because Einstein's theory suggests faster than light speed is impossible doesn't mean it is impossible. If Einstein were a young man today, picking up where his old self left off, he'd be the first one to give the light speed limit its proper context. |
anon331081 Post 4 |
Can you visualize going faster than the speed of light without violating Einstein's theory? It's not difficult if you understand the nature of e-m energy, mass physics, and normal space. Special Relativity is only a limit if you allow it to be. Open your mind! |
anon152304 Post 3 |
Can effect give rise to its cause? If not, then all else must follow as a matter of consequence. |
anon128530 Post 2 |
Einstein is 100 percent correct. There is no speed faster than light, if so then theoretically time travel would be possible (if you go fast enough, you would be going backward). We can reach close to the speed of light but we will never get there. |
anon127076 Post 1 |
I think that Einstein's Special Relativity must correct the light velocity which is constant. Because if space and time change, then Light velocity also changes. We must find that the light velocity: c=300,000km/s is different from the light velocity: c'=300,000 km'/s'. (of which km, km' are denoted by space and s, s' are denoted by time) --Le |