No, it does not. It just looks that way to a distant observer.Jacob Gable said:I'm not a physicist so I am very igorant on this subject. From I know time gets slower and slower as you approach a black hole
Correct.and an outside observer would never actually see matter being gobbled up.
The matter being eaten appears to slow down as it approaches the Event Horizon but we see it headed that way and infer correctly that despite how it looks to us, it is in fact falling into the Event Horizon.But I have read about stars get observed getting eaten away. How is this possible?
just like everything else in the universe moves.And how do black holes move?
Since time does NOT slow down, there's no issue.If time essentially stops in one how do we observe it move in space?
That's what Leonard Susskind believes and finally convinced Stephen Hawking of (Google "The Holographic Principle"). Personally, I just don't get the holographic principle at all but I do concede that those guys know more than I do.RelativeRelativity said:Might I ask whether its true that matter or energy falling into a black hole always leaves information on the event horizon?
(Talk about Big Brother surveillance...)
Yes, but an electron can NOT be everywhere at once. That's another pop-sci fallacy. It can be ANYWHERE until measured, but that's a far cry from being everywhere at once.RelativeRelativity said:Thank you, I'm a little familiar. If I believe an electron can be everywhere at once I'm at the mercy of experts from there on lol
A black hole is an astronomical object with a gravitational pull so strong that nothing, including light, can escape from it. It is formed when a massive star dies and its core collapses under the force of its own gravity.
We cannot directly observe black holes, but we can observe their effects on nearby objects. For example, we can see the light emitted by matter that is being pulled into a black hole, or observe the distortion of light as it passes near a black hole.
According to Einstein's theory of relativity, the strong gravitational pull of a black hole causes time to slow down near its event horizon (the point of no return). This effect, known as time dilation, means that time moves slower for an observer near a black hole compared to an observer further away.
No, nothing can escape from a black hole once it has passed the event horizon. This includes light, matter, and even information. Anything that gets too close will be pulled in and crushed at the singularity, the point of infinite density at the center of a black hole.
Black holes do not move in the traditional sense, as they are not propelled by any external forces. However, they can grow in size by absorbing matter and merging with other black holes. This can cause them to move through space at high speeds, but their movement is primarily determined by the gravitational pull of other objects in their vicinity.