When an atom is smashed in a black hole, its particles are torn apart due to the extreme gravitational forces. The subatomic particles are then absorbed into the black hole, adding to its mass and energy. The energy released during this process can contribute to the black hole's growth and power its intense gravitational pull.
If the valence orbital of an atom is full, the atom is stable and less likely to interact with other atoms to form chemical bonds. This is because a full valence orbital fulfills the octet rule, meaning the atom has attained a more stable electron configuration.
The hole numbers on the top of each element represent the atomic number. This number indicates the number of protons in the nucleus of an atom of that element. It is a unique identifier for each element on the periodic table.
In a photocell, the charge of a hole is positive. Holes are essentially empty spaces in a crystal lattice where an electron has moved away, leaving behind a positive charge that can move through the material similar to a positively charged particle.
The two parts of a black hole are the event horizon and the singularity. The event horizon is the "surface" of the black hole, and is imaginary. The event horizon's appearance is caused by the bending of light. The singularity is a point of space where everything that gets sucked in is crushed to about the size of an atom.
None. There is no part of an atom that would not get pulled into a black hole.
It says "floof!"
No a "hole" is not a particle, in solid state electronics a "hole" is a positively charged virtual charge carrier caused by the absence of an electron (which is a particle) from the atom's valence band. A "hole" has some properties making it act similar to a particle, but it is not one.
The regular electronic structure of 4 bonding electrons per atom is frustrated, because the gallium provides only 3. This situation is called "a hole in the valence band". If an electron jumps from a nearby silicon atom to fill this hole, there appears a hole where it came from (so it looks like the hole has moved, as it indeed has). This movement can be influenced by electric fields, and is called p-type, or hole, conduction (which is strictly electron movements in the "valence" band of the silicon).
Either be ripped a part atom by atom you be compressed smaller than a molecule
Basically none. No atom will survive the forces in a black hole. (However, all the mass that falls into the black hole will still be there.)
If you are talking about a black hole, then you get squished into a ball smaller than an atom and keep going, or time can change.
When an atom is smashed in a black hole, its particles are torn apart due to the extreme gravitational forces. The subatomic particles are then absorbed into the black hole, adding to its mass and energy. The energy released during this process can contribute to the black hole's growth and power its intense gravitational pull.
The theory is that there is a hole at the center of the universe, but that it is smaller then the size of an atom. Otherwise nothing is really known
they form on the scrotum of the hydrogen atom and the testicles from the other atom jam up in the hydrogen's b-hole
If the valence orbital of an atom is full, the atom is stable and less likely to interact with other atoms to form chemical bonds. This is because a full valence orbital fulfills the octet rule, meaning the atom has attained a more stable electron configuration.
The hole numbers on the top of each element represent the atomic number. This number indicates the number of protons in the nucleus of an atom of that element. It is a unique identifier for each element on the periodic table.