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Yes, it is compulsory that either the attractive forces or the repulsive forces be stronger.an atom has either +ve charge or -ve charge.if positive charge is stronger than negative charge in any atom then forces of attraction will be stronger. if positive charge is weaker than negative charge then forces of repulsion will dominate.
The electrostatic repulsion.
The electrostatic repulsion.
attraction forces between the electrons of one atom and the nucleus of the other atom are balanced by the repulsive force caused by the two + charged nuclei as they are forced together~attractive forces have a little attraction for the atoms.
attraction
lattice energy
No. The mass of electrons is so small that the repulsion due to their equal electric charges is much greater than the gravitational attraction between them, at any separation distance.
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.
The strong force holds the nucleus together against the repulsion between the electric charges of the protons.
Yes, it is compulsory that either the attractive forces or the repulsive forces be stronger.an atom has either +ve charge or -ve charge.if positive charge is stronger than negative charge in any atom then forces of attraction will be stronger. if positive charge is weaker than negative charge then forces of repulsion will dominate.
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".
Covalent bonds will always be stronger then an dipole or charge attraction between molecules.
When electrons are shared between atoms, the nuclei of both atoms experience attraction towards the electrons and vice versa. At a certain distance, the attraction is maximal because the repulsion between the nuclei is small while the attraction of each nuclei to the electrons is strong. Thus, the atoms are held together by their attraction to the shared electrons.
Covalent bonds in ions or electric attraction.
The nucleus consists of protons and neutrons. Inside the nucleus, there is an electrostatic force of repulsion between the protons. Those protons have positive charges, and like charges repel. Also acting in the nucleus is a force of attraction called the nuclear force. It provides the nuclear binding energy to keep the nucleus together. This nuclear force is a short range force, and is so strong that it will overcome the effect of the force of repulsion between the protons.
The lines in each diagram represent an electric field. The stronger the field, the close together the lines are.
This is electrostatic attraction, that tends to bring together electrical charges with different sign. Ions do not collapse one into the other since when the get to near, repulsion between external electrons orbitals counterbalance the electrostatic force created by the net ions charge.