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Physics
Classical Physics
Electromagnetism
Voltage vs Charge: Capacity & Applied Voltage
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[QUOTE="Drakkith, post: 6017800, member: 272035"] Voltage is the [I]difference in electric potential[/I] between two points. Electric potential is the amount of work needed to move a unit positive charge from a reference point to a specific point in an electric field. We typically use infinity as the reference point. Imagine we have two points in an electric field and we find their respective electric potentials. If the two potentials are not the same, then it requires that net work be performed to move a charge between the two points. This work can be positive if you have to work against the electric field, or negative if the electric field is doing the work for you. When we set up a voltage in an electric circuit we are setting up a situation where there is a difference in the electric potential between the different points in the circuit. This voltage drives a current through the circuit and allows us to create complex circuits to do things like run motors or electronic devices. Note that all of these terms, electric potential, voltage, and etc, are just ways of describing what the electric field is doing. When we say that the voltage causes a current to flow we mean that the electric field is in a particular configuration that makes it generate a current in a circuit. It is the electric field that does the work, not the voltage itself. Let's look at a couple of specific situations: 1. Keeping plates static and changing the number of charges on the plate. 2. Moving the plates while keeping the number of charges on the plates constant. 3. Changing the size of the plates while keeping their separation and number of charges constant. In example 1, changing the number of charges on each plate changes the voltage. Increasing the number of charges increases the voltage and vice versa. Easy example. No surprises here. In example 2, moving the plates apart [I]increases[/I] the voltage of the capacitor. This is because the voltage for a capacitor is given by ##V=\int_0^d E \, ds = E\int_0^d \, ds = Ed##, where ##E## is the electric field (taken to be constant here because the field lines between the parallel plates are straight lines and we are ignoring the field lines near the fringe) and ##d## is the distance between the plates. You can imagine that a unit positive test charge placed near the positive plate will accelerate for a greater time and distance when the plates are far apart, giving it a higher kinetic energy when it finally reaches the negative plate. Conversely, moving the plates closer together while keeping the number of charges static will decrease the voltage. Interestingly, moving the plates apart [I]decreases[/I] the [I]capacitance[/I] of the capacitor. Since we just found that moving the plates apart increases the voltage if we hold the number of charges on each plate constant, that means that it requires a larger and larger applied voltage to put the same number of charges on each plate as we move the plates apart. Hence the capacitance decreases per the equation ##C=\frac{Q}{V}## since ##Q## is constant and ##V## increases. In example 3, changing the area of the plates while keeping the number of charges and the separation constant will also alter the voltage. Imagine that we take our charged capacitor and we quickly weld on a neutral conductor to each plate such that the area of each plate doubles. The charges on each plate will quickly spread out and the end result is that the density of charges on each plate decreases. The causes a corresponding drop in the density of the field lines between the plates and, since the density of the field lines represents the magnitude of the electric field, the magnitude of the E-field between the plates decreases. This makes sense, since a test charge placed near one of the plates will find that many of the charges have now moved further away from it after welding on the neutral conductors. The contribution of those charges on our test charge is reduced, reducing the magnitude of the force felt by that test charge. The end result is that the voltage between the plates decreases when we increase the area of the plates while keeping the number of charges and separation constant. Put another way, if we increase the area of the plates, we can put more charges on each plate for the same applied voltage. This also increases the capacitance of the capacitor per the capacitance equation I provided in example 2. So we have more than one way of altering the voltage on a capacitor, only one of which involves altering the number of charges on each plate. [/QUOTE]
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Voltage vs Charge: Capacity & Applied Voltage
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