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 strong nuclear force is stronger than the electric repulsion between protons at very small distances within the nucleus. It is responsible for holding protons and neutrons together in the nucleus despite the electromagnetic repulsion between protons.
Protons in the nucleus are tightly bound together by the strong nuclear force, which is stronger than the electromagnetic repulsion between positively charged protons. Electrons, on the other hand, are much lighter and are located further away from each other in the electron cloud surrounding the nucleus, resulting in weaker repulsive forces between them.
Protons in the nucleus of an atom are held together by the strong nuclear force, which is stronger than the electromagnetic force that causes repulsion between positively charged particles. This strong force overcomes the electromagnetic repulsion, keeping the protons bound in the nucleus. If the balance between these forces is disrupted, such as in nuclear fission reactions, the nucleus can split apart.
Since a nucleus is made of proton, positively charged particle, you would assume that it would tend to push itself apart. However the presence of neutron allows the charge to be distributed and therefore make it more stable.
Atomic nuclei are positively charged and contain protons and neutrons. The number of protons in the nucleus determines the element, while the number of neutrons can vary within isotopes of the same element. Nuclei are held together by the strong nuclear force, which overcomes the electromagnetic repulsion between positively charged protons.
The strong nuclear force is stronger than the electric repulsion between protons at very small distances within the nucleus. It is responsible for holding protons and neutrons together in the nucleus despite the electromagnetic repulsion between protons.
Protons in the nucleus are tightly bound together by the strong nuclear force, which is stronger than the electromagnetic repulsion between positively charged protons. Electrons, on the other hand, are much lighter and are located further away from each other in the electron cloud surrounding the nucleus, resulting in weaker repulsive forces between them.
The strong force is responsible for holding protons and neutrons together within the nucleus of an atom. It is the strongest force in nature, overcoming the electromagnetic repulsion between positively charged protons.
The strong nuclear force is responsible for the stability of particles like protons and neutrons within the atomic nucleus. This force is attractive and acts to overcome the repulsion between positively charged protons, holding the nucleus together.
The repulsive force between proton-proton pairs inside the nucleus is called the electrostatic repulsion force. This force arises due to the positively charged protons within the nucleus experiencing mutual repulsion because they all have the same charge.
Electrostatic forces within the nucleus primarily play a role in holding the protons together due to the strong nuclear force. This force overcomes the electrostatic repulsion between positively charged protons, allowing nuclei to stay intact. The electrostatic forces between protons and electrons also contribute to the stability of atoms.
The strong nuclear force acts over very short distances within atoms, typically within the nucleus itself, which is on the order of femtometers (10^-15 meters). This force is responsible for binding protons and neutrons together in the nucleus despite the electrostatic repulsion between protons.
No, it is attractive. The strong nuclear force, as it is known, is what overcomes the coloumbic repulsion of the positively charged protons, which would otherwise tend to fly apart due to the electromagnetic force (like charges repulse).
The particle responsible for holding the nucleus together is the strong nuclear force mediated by particles called gluons. This force overcomes the electrostatic repulsion between positively charged protons within the nucleus, keeping it stable.
Protons and neutrons together in the nucleus
Protons in the nucleus of an atom are held together by the strong nuclear force, which is stronger than the electromagnetic force that causes repulsion between positively charged particles. This strong force overcomes the electromagnetic repulsion, keeping the protons bound in the nucleus. If the balance between these forces is disrupted, such as in nuclear fission reactions, the nucleus can split apart.
protons and neutrons are both made of quarks each with their own +'ve and -'ve charges, at the close proximity that protons and neutrons are found their overall charges are no longer in effect it's the charges of the quarks within them that affect attraction and repulsion