By keeping it inside in a hollow conducting sphere.
This process is known as electrostatic shielding.
In atomic nuclei with a large number of protons, such as those with atomic numbers greater than 83, the strong nuclear force is greater than the electrostatic force. This is because the strong force acts over a very short range and helps to overcome the electrostatic repulsion between positively charged protons, which becomes more significant with increasing atomic number.
In small atomic nuclei with few protons and neutrons, the strong nuclear force is greater than the electrostatic force between the positively charged protons, allowing the nucleus to stay together. As the nucleus gets larger with more protons, the electrostatic force becomes stronger and may overcome the strong nuclear force, leading to instability and possible radioactive decay.
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.
It causes the protons in the nucleus repel each other.
When the repulsive strong nuclear force overcomes the attractive electrostatic force within an atom's nucleus, this can cause the atom to become unstable and radioactive. The imbalance leads to the emission of particles or energy in order to achieve a more stable configuration. This process is known as radioactive decay.
The bond in magnesium fluoride is ionic.
strong
The strong forces of attraction between the positive and negative regions of molecules are called electrostatic forces or electrostatic interactions.
Gravitational, electrostatic, strong nuclear, and weak nuclear
Gravitational, electrostatic, strong nuclear, and weak nuclear
An imbalance between the electrostatic and strong nuclear forces
Strong yet sensitive!
-- gravitational -- electrostatic -- magnetic -- weak nuclear -- strong nuclear
gravitational force electrostatic force weak nuclear force strong nuclear force
A nucleus is stable if the electrostatic and strong nuclear forces balance out.
Two protons alone won't stick together - their electrostatic repulsion is too strong. If there are also neutrons involved, the strong force can become stronger than the electrostatic repulsion - for example, in the simplest case of Helium-3, two protons and one neutron will stick together. The neutron helps provide the strong force to keep the protons together; the two protons by themselves don't have enough attraction through the strong force to overcome the electrostatic repulsion.
In atomic nuclei with a large number of protons, such as those with atomic numbers greater than 83, the strong nuclear force is greater than the electrostatic force. This is because the strong force acts over a very short range and helps to overcome the electrostatic repulsion between positively charged protons, which becomes more significant with increasing atomic number.