nucleons are made of nuclear molecules. these specific types of molecules are sensitive to strong forces like gravity and other forces like black holes.
The strong interaction, also known as the strong nuclear force or the strong force. This force is about 100 times stronger than the electromagnetic force that would be repelling the protons away from each other.
The electro-magnetic force, I guess. The strong nuclear force holds the nucleons together and the electro-magnetic tries to push them apart.
Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.
The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.
Electrically the protons repel each other, right? So what keeps them united? The answer is that there is a stronger force between nucleons - protons and neutrons. This force is called the "strong force". The strong force between two protons is not strong enough to keep them together (against the electrostatic force); but if there are some neutrons present, the situation changes, because the strong force acts between protons, but also between protons and neutrons.
It is the force between the nucleons within the nucleus. It is due to the exchange of mesons in between the nucleons. This force is a strange one and it has shortest range. It is some 1040 times greater than the gravitational attractive force between the nucleons.
The strong force hold quarks together in nucleons and holds nucleons together. The electromagnetic force holds the electrons in the atom.
and the fact that it is stable to estimate the strength of the strong nuclear force between nucleons. assume the distance between nucleons is 10−15 m
The strong interaction, also known as the strong nuclear force or the strong force. This force is about 100 times stronger than the electromagnetic force that would be repelling the protons away from each other.
The electro-magnetic force, I guess. The strong nuclear force holds the nucleons together and the electro-magnetic tries to push them apart.
The force binding the individual nucleons (neutrons and protons) together inside the nucleus of an atom. :)
The strong nuclear, or "color," force. (Technically, the color force holds the protons and neutrons themselves together; the force that holds the nucleons to other nucleons is the residual color force.)
The force between nucleons is called nuclear force.
The Standard Model of particle theory states that nucleons are bound together primarily by the Strong Interaction Force. These forces keep protons and neutrons together.
The strong atomic force holds protons (and neutrons) together in the nucleus.
Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.
The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.