The attraction or repulsion between electric charges is stronger when they are closer together and weaker when they are far apart. This is described by Coulomb's law, which states that the force between two charges is directly proportional to the product of the charges and inversely proportional to the square of the distance between them.
Attraction or repulsion of electric charges is called electrostatic force. This force can either attract opposite charges together or repel like charges apart.
The strong nuclear force is stronger than the repulsion between protons. The strong nuclear force is responsible for holding the nucleus together by overcoming the electrostatic repulsion between positively charged protons.
The strong nuclear force is much stronger than the electric force of repulsion, by about 100 times at nuclear distances. This is what allows protons and neutrons to be held together in the nucleus despite the repulsive electric forces between positively charged protons.
The force that pulls particles together is called the electromagnetic force. This force is responsible for the attraction between particles with opposite electric charges and the repulsion between particles with like charges.
Magnetic attraction is the force that pulls two magnets together, while magnetic repulsion is the force that pushes two magnets apart. These phenomena arise from the alignment of magnetic domains within the magnets, which either reinforce each other (attraction) or oppose each other (repulsion). Magnetic attraction and repulsion follow the laws of magnetism and are essential for the functioning of many devices, such as electric motors and generators.
Attraction or repulsion of electric charges is called electrostatic force. This force can either attract opposite charges together or repel like charges apart.
The strong nuclear force is stronger than the repulsion between protons. The strong nuclear force is responsible for holding the nucleus together by overcoming the electrostatic repulsion between positively charged protons.
The strong nuclear force is much stronger than the electric force of repulsion, by about 100 times at nuclear distances. This is what allows protons and neutrons to be held together in the nucleus despite the repulsive electric forces between positively charged protons.
The force that pulls particles together is called the electromagnetic force. This force is responsible for the attraction between particles with opposite electric charges and the repulsion between particles with like charges.
Magnetic attraction is the force that pulls two magnets together, while magnetic repulsion is the force that pushes two magnets apart. These phenomena arise from the alignment of magnetic domains within the magnets, which either reinforce each other (attraction) or oppose each other (repulsion). Magnetic attraction and repulsion follow the laws of magnetism and are essential for the functioning of many devices, such as electric motors and generators.
Electrical charges experience forces that depend on their position and the strength of the electric field. Charges closer together experience stronger forces of attraction or repulsion due to the electric field being more intense. The strength of the electric field decreases with distance from the source charge, affecting how charges interact with each other based on their positions.
The electric force is a fundamental force of nature that describes the attraction or repulsion between electrically charged particles. It is responsible for holding atoms and molecules together, creating electrical currents in wires, and powering electronic devices like computers and smartphones. Understanding and controlling the electric force is crucial in fields such as engineering, physics, and technology.
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".
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.
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.
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.