ez
The strong nuclear force, one of the four fundamental forces of nature, holds the positively charged protons together in the nucleus. This force is stronger than the electromagnetic force, which causes protons to repel each other due to their positive charges. The balance between these forces is what keeps the nucleus intact.
Scientists believe that a strong force must be present to keep the nucleus of an atom intact because protons, which are positively charged, repel each other due to their electromagnetic forces. The strong nuclear force is able to overcome this repulsion and bind the protons and neutrons together in the nucleus.
The nucleus remains intact due to the strong nuclear force, which is a fundamental force that acts between protons and neutrons, binding them together within the nucleus. This force is much stronger than the electromagnetic repulsion between positively charged protons, allowing the nucleus to maintain its stability. Additionally, the balance between the number of protons and neutrons contributes to nuclear stability, with certain ratios allowing for stronger binding and reducing the likelihood of spontaneous splitting or decay.
the nucleus intact
The fundamental force that binds the nucleus of atoms together is the strong nuclear force. This force acts between protons and neutrons, overcoming the electromagnetic repulsion between positively charged protons to hold the nucleus intact. It is the strongest of the four fundamental forces but operates over a very short range, typically only effective at the scale of atomic nuclei.
The strong nuclear force, one of the four fundamental forces of nature, holds the positively charged protons together in the nucleus. This force is stronger than the electromagnetic force, which causes protons to repel each other due to their positive charges. The balance between these forces is what keeps the nucleus intact.
Scientists believe that a strong force must be present to keep the nucleus of an atom intact because protons, which are positively charged, repel each other due to their electromagnetic forces. The strong nuclear force is able to overcome this repulsion and bind the protons and neutrons together in the nucleus.
The nucleus contains neutral 'neutrons' ('What is in a name', W. Shakespeare) and positive 'protons'. Negative electrons are orbiting around this nucleus, which itself is positively charged.
The nucleus remains intact due to the strong nuclear force, which is a fundamental force that acts between protons and neutrons, binding them together within the nucleus. This force is much stronger than the electromagnetic repulsion between positively charged protons, allowing the nucleus to maintain its stability. Additionally, the balance between the number of protons and neutrons contributes to nuclear stability, with certain ratios allowing for stronger binding and reducing the likelihood of spontaneous splitting or decay.
the nucleus intact
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 nuclear force is what binds the nucleons, which are protons and neutrons, together in the nucleus of an atom. The binding energy is the amount of energy needed to break the atom apart. The one is a force, and the other is a measurement.
The fundamental force that binds the nucleus of atoms together is the strong nuclear force. This force acts between protons and neutrons, overcoming the electromagnetic repulsion between positively charged protons to hold the nucleus intact. It is the strongest of the four fundamental forces but operates over a very short range, typically only effective at the scale of atomic nuclei.
Despite the long fall, the toy was still intact. She had kept the room intact, exactly as he left it.
The nucleus is intact and the genetic material has the appearance of chromatin.
The nuclear membrane keeps material in the nucleus from spilling out. There is a similar membrane that surrounds the cells as well.
The energy stored in the nucleus is called nuclear energy. It is released when the bonds holding the nucleus of an atom together are either broken (nuclear fission) or formed (nuclear fusion). This energy is the source of power for nuclear reactors and nuclear weapons.