When unlike charges come in contact, electrons transfer from the object with excess electrons (negative charge) to the object lacking electrons (positive charge). This equalizes the charge between the two objects, resulting in a neutral charge overall.
When two unlike charges come together, they will attract each other due to the electrostatic force. This attraction will cause the charges to move closer together until they reach a point of equilibrium where the electrostatic force is balanced with other forces.
Opposite charges attract each other due to the electric force. When they come in contact, electrons from the negatively charged object will transfer to the positively charged object until both objects are neutral.
Objects with unlike charges are attracted to each other due to the electrostatic force of attraction. When they come into contact, electrons may transfer from one object to another, resulting in both objects becoming neutral. This process aims to balance out the charges and reach a state of equilibrium.
Electrons are the electric charges that are transferred between objects in contact. When two objects come into contact, electrons can move from one object to the other, resulting in a transfer of charge.
That depends on what the charges are. There's an easy rule: opposites attract. So if one is positive and one is negative, they'll be attracted (the greater the charges, the greater the attraction), while if they are both positive or both negative, they'll be repelled (again, the greater the charges, the more they'll be repelled).
When two unlike charges come together, they will attract each other due to the electrostatic force. This attraction will cause the charges to move closer together until they reach a point of equilibrium where the electrostatic force is balanced with other forces.
Objects with unlike charges attract each other due to the electrostatic force of attraction between them. This force pulls the objects towards each other until they come into contact, neutralizing the charges.
Opposite charges attract each other due to the electric force. When they come in contact, electrons from the negatively charged object will transfer to the positively charged object until both objects are neutral.
Objects with unlike charges are attracted to each other due to the electrostatic force of attraction. When they come into contact, electrons may transfer from one object to another, resulting in both objects becoming neutral. This process aims to balance out the charges and reach a state of equilibrium.
When a positive charge and a negative charge come into contact, they will attract each other due to their opposite charges. This attraction can lead to the exchange of electrons between the two charges, resulting in neutralization.
they repel
When two neutral electrical charges come in contact, there is no transfer of electrons between them. They will remain neutral and there will be no repulsion or attraction between them.
CFC's when come in contact with ozone deplete it. It reacts with it and decomposes it.
Electrons are the electric charges that are transferred between objects in contact. When two objects come into contact, electrons can move from one object to the other, resulting in a transfer of charge.
That depends on what the charges are. There's an easy rule: opposites attract. So if one is positive and one is negative, they'll be attracted (the greater the charges, the greater the attraction), while if they are both positive or both negative, they'll be repelled (again, the greater the charges, the more they'll be repelled).
If two positively charged objects come into contact, they will repel each other due to the like charges. The positive charges will try to move away from each other, resulting in a force of repulsion.
The potential energy of two like charges is positive because work must be done to bring them together against their natural repulsion. Conversely, the potential energy of two unlike charges is negative because work is released when they come together and move into a lower potential energy state.