This has the same
effect as a black hole's event horizon, the point of no return for light: an observer outside an event horizon could see nothing inside, as no light can escape the black hole's gravity to cross the horizon to the universe outside.
Not exact matches
but i have a new idea for what believers think god is... and it may actually exist and funny enough is only tested thru its
effect on other objects — kinda like a
black hole — the collective conscienceness of every living thing... since we all are part of the same energies and have in some form or another a conscienciness, i believe that collective is what the believers claim is god — the collective being felt and moved like any conscienceness but with the power to
effect us all
as we all play into it —
as long
as we are open to it... your thoughts?
As G2 swings closer to the
black hole's event horizon — the point past which even light can not escape — gravity has already stretched its leading edge into a ribbon more than 90 billion miles long, pulling it away from the tail, which isn't yet feeling the
black hole's full
effects.
The Nottingham experiment was based on the theory that an area immediately outside the event horizon of a rotating
black hole — a
black hole's gravitational point of no return — will be dragged round by the rotation and any wave that enters this region, but does not stray past the event horizon, should be deflected and come out with more energy than it carried on the way in — an
effect known
as superradiance.
If the new force does exist, we might soon be able to see its
effects on things influenced by dark matter, such
as the behaviour of
black holes or the masses of the first stars, says Douglas Finkbeiner of Harvard University, who was not involved in the new study.
These particles would in
effect serve
as recording devices that store information, providing clues about the original material that went into the
black hole.
No one has actually seen a
black hole, he says, and anything with a tremendous amount of gravity — such
as the supermassive remnants of stars — could exert
effects similar to those researchers have blamed on
black holes.
The team interpreted those shifts
as the
effect of cyclonic winds moving above and below the
black hole at speeds of about 4000 kilometers per second, tens of thousands of times stronger than the most intense cyclones on Earth.
As well as producing Oscar - nominated visual effects for the movie, Thorne and the effects team also unearthed some unexpected physics, such as that an observer close to a rapidly spinning black hole would see more than a dozen images of individual stars just outside one edge of the black hole's «shadow.&raqu
As well
as producing Oscar - nominated visual effects for the movie, Thorne and the effects team also unearthed some unexpected physics, such as that an observer close to a rapidly spinning black hole would see more than a dozen images of individual stars just outside one edge of the black hole's «shadow.&raqu
as producing Oscar - nominated visual
effects for the movie, Thorne and the
effects team also unearthed some unexpected physics, such
as that an observer close to a rapidly spinning black hole would see more than a dozen images of individual stars just outside one edge of the black hole's «shadow.&raqu
as that an observer close to a rapidly spinning
black hole would see more than a dozen images of individual stars just outside one edge of the
black hole's «shadow.»
Theoretical physicist Kip Thorne of the California Institute of Technology in Pasadena, who came up with the original idea for the movie, worked closely with the London - based special
effects company Double Negative to ensure that the wormhole and
black hole shown were
as realistic
as possible.
As the atoms, attracted to the breach, zipped across it at more than four times the speed of sound, they gave rise to a
black hole effect.
As such, researchers want to look at as many early supermassive black holes as possible to learn more about their growth and their effects on the rest of the cosmo
As such, researchers want to look at
as many early supermassive black holes as possible to learn more about their growth and their effects on the rest of the cosmo
as many early supermassive
black holes as possible to learn more about their growth and their effects on the rest of the cosmo
as possible to learn more about their growth and their
effects on the rest of the cosmos.
As we noted, the LHC will not destroy the world and as George Musser wrote to me after we recorded the interview, «I said something to the effect that scientists had stocked [stoked] concerns about black holes by saying the LHC would create particles not seen since the big bang, but those particles have been seen since the big bang, namely in natural processes such as cosmic ray collisions; therefore if black holes posed a threat, the universe would already be a goner.&raqu
As we noted, the LHC will not destroy the world and
as George Musser wrote to me after we recorded the interview, «I said something to the effect that scientists had stocked [stoked] concerns about black holes by saying the LHC would create particles not seen since the big bang, but those particles have been seen since the big bang, namely in natural processes such as cosmic ray collisions; therefore if black holes posed a threat, the universe would already be a goner.&raqu
as George Musser wrote to me after we recorded the interview, «I said something to the
effect that scientists had stocked [stoked] concerns about
black holes by saying the LHC would create particles not seen since the big bang, but those particles have been seen since the big bang, namely in natural processes such
as cosmic ray collisions; therefore if black holes posed a threat, the universe would already be a goner.&raqu
as cosmic ray collisions; therefore if
black holes posed a threat, the universe would already be a goner.»
This results in familiar phenomena like orbiting moons, planets and stars,
as well
as some stranger
effects like cosmic ripples and
black holes.
Astronomers call this
effect gravitational lensing, and it's one of the primary methods of detecting unobservable cosmic phenomena such
as black holes.
As black holes are gravitational monsters, they're governed by Einstein's general relativity, so by studying the gravitational waves they produce when they collide, scientists also can study the waves for an effect known as «dispersion.&raqu
As black holes are gravitational monsters, they're governed by Einstein's general relativity, so by studying the gravitational waves they produce when they collide, scientists also can study the waves for an
effect known
as «dispersion.&raqu
as «dispersion.»