Using our microscopic model of the atom, we can now talk about how objects become charged (called charging) and how they return to being neutral (often called discharging). These notes will discuss how these processes occur and how they are different for insulators and conductors.
Objects become charged by either gaining extra electrons (becoming negatively charged) or by giving up electrons (becoming positively charged). There are generally two ways to create charged objects: by conduction or by induction.
Conduction with an insulator: When you use conduction to add charge to an insulator, the charges stay very close to the same location where they are placed because charges are not free to move through an insulator. In the case of the tape, which is a pretty good insulator, the charges are on the sticky side of the upper tape and the non-sticky side of the lower tape because those are the surfaces in contact. The charges on the sticky side of the upper tape are unable to move to the non-sticky side because tape is an insulator.
Conduction with a conductor: When you use conduction to add charge to a conductor, the charges are free to move and will spread out evenly through the conductor. This is because the added charges (of the same sign) will repel each other. If the material is a conductor, these charges are free to move through the material, and will disperse evenly so that each charge is as far away from the others as possible.
Discharging occurs when excess charges leave a charged object, often, making it return to its original, neutral state. When you were dealing with the charged pieces of tape, you may have noticed that if you touched the tape or let it sit for too long there was no longer charge on the tape - it had discharged. If you let the tape sit for too long, the tape will discharge because the water molecules in the air (which are polarized because of the shape of the molecule) act as small conductors and are able to remove charges when they bounce into the tape. This is also why your clothes have more static in the winter (drier air) than they do in the summer (more humid air).
If you touch the tape, your finger acts as a neutral conductor and the charges are able to move from the tape into your finger. Unfortunately, you cannot shock your friend using your finger because the charges then spread through your body and you are not adding enough charge compared to all the charges and atoms in your body to be able to notice. We call a vast collection of positive and negative charges an electrical ground or just ground (it is called ground because the Earth is typically used as an electrical ground). A ground is able to absorb small amounts of charge and remain neutral because the added charge is so small compared to the total number of charges in the ground. In the tape example, your body was acting as a ground. The symbol for a ground is three horizontal lines, decreasing in size (shown to the right).
From the calculation side, dealing with discharging objects is dependent on time and is very complicated. For the purpose of this class, we will often make the assumption that discharging does not occur. Another way to say this would be that we assume charge is constant, or we assume that the charged object does not interact with the air or another surface.