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.
Inside the nucleus of an atom, the primary forces at work are the strong nuclear force and the electromagnetic force. The strong nuclear force, which acts between nucleons (protons and neutrons), is the dominant force that holds the nucleus together, overcoming the repulsive electromagnetic force between positively charged protons. This strong force operates at very short distances, binding nucleons tightly within the nucleus. Additionally, the weak nuclear force plays a role in certain types of nuclear reactions, but it is not responsible for holding the nucleus together.
The strong force, mediated by particles called gluons, acts between nucleons (protons and neutrons) within the atomic nucleus. It is a short-range force that primarily works to bind quarks together within nucleons and hold the nucleus together. This force is attractive, overcoming the electromagnetic repulsion between positively charged protons in the nucleus.
The force between nucleons is called nuclear force.
Yes, the protons help hold an atomic nucleus together. Let's look at things and figure this one out. Protons are positively charged, as you know, and like charges repel. That's basic electrostatics. The Coulomb forces of the protons push them away from each other. Further, when protons are packed into an atomic nucleus, they're still pushing away from each other. Let's consider what happens when an atomic nucleus forms. The term nucleon is how we refer to protons and neutrons when they are used as building blocks of an atomic nucleus. And the nucleons all undergo what is called mass deficit when that atomic nucleus if forced together in nuclear fusion. All the nucleons lose some mass during the fusion process, and this mass is converted into nuclear binding energy. The nuclear binding energy is also called nuclear glue, or residual strong interaction (residual strong force). And it is this force that overcomes the repulsive force of the protons, and it keeps the nucleus together. It turns out that both the protons and neutrons are involved in the "magic" that holds the nucleus together, as we've seen. Certainly the protons cannot do it by themselves, and the neutrons are necessary. But the protons have to give up some mass as well so that residual strong force can appear and mediate the fusion process that holds the nucleus together. It's really that simple.
This is called the strong nuclear force, at close range it overcomes electrostatic repulsion between protons. This force had to be deduced from the stability of nuclei, but theoretical physicists are still trying to explain what it really is and how it works.
The strong force hold quarks together in nucleons and holds nucleons together. The electromagnetic force holds the electrons in the atom.
There is a stronger force, stronger than the electrostatic force, that keeps nucleons (protons and neutrons) together. It is not enough to hold two protons together if they are alone, but the neutrons provide additional attraction. This force is known as the "strong force".There is a stronger force, stronger than the electrostatic force, that keeps nucleons (protons and neutrons) together. It is not enough to hold two protons together if they are alone, but the neutrons provide additional attraction. This force is known as the "strong force".There is a stronger force, stronger than the electrostatic force, that keeps nucleons (protons and neutrons) together. It is not enough to hold two protons together if they are alone, but the neutrons provide additional attraction. This force is known as the "strong force".There is a stronger force, stronger than the electrostatic force, that keeps nucleons (protons and neutrons) together. It is not enough to hold two protons together if they are alone, but the neutrons provide additional attraction. This force is known as the "strong force".
The force between nucleons is called nuclear force.
The force between nucleons is called nuclear force.
Nucleons, which are protons and neutrons, are held together by the strong nuclear force. This force overcomes the electrostatic repulsion between positively charged protons in the nucleus, keeping the nucleus stable.
The force between nucleons is called nuclear force.
The force between nucleons is called nuclear force.
The force between nucleons is called nuclear force.
The strong atomic force holds protons (and neutrons) together in the nucleus.
The strong nuclear force overcomes the repulsive force of protons, holding them together in the nucleus. This force is much stronger than the electromagnetic force that causes the repulsion between the positively charged protons.
The force binding the individual nucleons (neutrons and protons) together inside the nucleus of an atom. :)
Inside the nucleus of an atom, the primary forces at work are the strong nuclear force and the electromagnetic force. The strong nuclear force, which acts between nucleons (protons and neutrons), is the dominant force that holds the nucleus together, overcoming the repulsive electromagnetic force between positively charged protons. This strong force operates at very short distances, binding nucleons tightly within the nucleus. Additionally, the weak nuclear force plays a role in certain types of nuclear reactions, but it is not responsible for holding the nucleus together.