A black hole is formed when a massive star collapses under its own gravity at the end of its life cycle. The key processes involved in its formation include the core of the star running out of nuclear fuel, leading to a rapid collapse and the formation of a singularity, a point of infinite density. This collapse causes the outer layers of the star to be expelled in a supernova explosion, leaving behind a dense core that can further collapse into a black hole if it is massive enough.
Black holes are formed when a massive star runs out of fuel and collapses under its own gravity. This collapse creates a singularity, a point of infinite density at the center of the black hole. The processes involved in their formation include the gravitational collapse of the star's core, followed by the expulsion of outer layers in a supernova explosion. The remaining core then collapses further to form a black hole.
A black hole has three main layers: the event horizon, the singularity, and the accretion disk. The event horizon is the point of no return where gravity is so strong that nothing can escape. The singularity is a point of infinite density at the center of the black hole. The accretion disk is a swirling disk of gas and dust that feeds the black hole. These layers contribute to the formation and behavior of a black hole by shaping its gravitational pull and determining how it interacts with its surroundings.
The presence of water does not directly affect the formation or behavior of a black hole. Black holes are formed from the collapse of massive stars and are characterized by their immense gravitational pull, which can even pull in light. Water, being a common substance on Earth, does not have a significant impact on the formation or behavior of black holes in space.
In a black hole, gravity is so strong that nothing, not even light, can escape. This means that whatever goes into a black hole is trapped inside forever, making the saying "what happens in a black hole stays in a black hole" true.
No, not every galaxy contains a black hole. While many galaxies do have a supermassive black hole at their center, there are also galaxies that do not have a black hole.
Black holes are formed when a massive star runs out of fuel and collapses under its own gravity. This collapse creates a singularity, a point of infinite density at the center of the black hole. The processes involved in their formation include the gravitational collapse of the star's core, followed by the expulsion of outer layers in a supernova explosion. The remaining core then collapses further to form a black hole.
It is not yet known for sure how a supermassive black hole acquires the enormous mass it has. It is possible that it starts as a normal black hole, and then gets more mass. It is also possible that from the start, a much larger amount of mass than in a normal black hole collapses.
Black Holes end up producing large quantities of gamma rays throughout their lives. This is one of the processes that lead to a Black Hole's demise.
A black hole has three main layers: the event horizon, the singularity, and the accretion disk. The event horizon is the point of no return where gravity is so strong that nothing can escape. The singularity is a point of infinite density at the center of the black hole. The accretion disk is a swirling disk of gas and dust that feeds the black hole. These layers contribute to the formation and behavior of a black hole by shaping its gravitational pull and determining how it interacts with its surroundings.
The presence of water does not directly affect the formation or behavior of a black hole. Black holes are formed from the collapse of massive stars and are characterized by their immense gravitational pull, which can even pull in light. Water, being a common substance on Earth, does not have a significant impact on the formation or behavior of black holes in space.
Gamma radiation emitted by black holes can originate from the accretion disk around the black hole or from high-energy processes within the black hole itself. This radiation can escape the gravitational pull of the black hole and travel through space, potentially affecting nearby objects or being detected by telescopes as a signature of black hole activity.
A black hole is what is left of an object that has completely collapsed under the force of gravity.
A black hole has a typical mass of around 4 times the mass of the sun at the time of formation. Mass has very little meaning for a blackhole otherwise.
a black hole froms when a massive star exhauists it's neclaer fule and goes through a supernova. The core collapese onto itself, until it reached critical mass.
You don't because your hands are not big enough and you don't have access to control over the processes involved.
The question makes no sense. Altitude has nothing at all to do with black hole formation. "Altitude" really only has any significant meaning in terms of Earth and humans, and it is as far as we know absolutely impossible to "make" a black hole at any altitude.
For one, a black hole can hardly be observed directly (the Hawking radiation is expected to exist, but it would be way too weak). A quasar (related to material falling into the black hole) is one way the black hole can be observed.Also, the quasar can play quite an active role in the formation of a galaxy.