Jantit... Macmillan: Quantit.. The energy of a charged capacitor is given by U = QV /2, where Q is the charge of All Bookm the capacitor and V is the potential difference across the capacitor. The energy of a charged capacitor can be described as the energy associated with the electric field In this part of the problem, you will express the energy of various types of capacitors in terms of their geometry and voltage. created inside the capacitor. In this problem, you will derive two more formulas for the energy of a charged capacitor; Part E you will then use a parallel-plate capacitor as a vehicle for obtaining the formula for the energy density associated with an electric field. It will be useful to recall the definition of capacitance, C = Q/V, and the formula for the capacitance of a parallel-plate capacitor, A parallel-plate capacitor has area A and plate separation d, and it is charged to voltage V. Use the formulas from the problem introduction to obtain the formula for the energy U of the capacitor. Express your answer in terms of A, d, V, and appropriate constants. C = co A/d, where A is the area of each of the plates and d is the plate separation. As usual, co is the permittivity of free space. DA AEd Submit Request Answer Let us now recall that the energy of a capacitor can be thought of as the energy of the electric field inside the capacitor. The energy of the electric field is usually described in terms of energy density u, the energy per unit volume. A parallel-plate capacitor is a convenient device for obtaining the formula for the energy density of an electric field, since the electric field inside it is nearly uniform. The formula for energy density can then be written as U = v . where U is the energy of the capacitor and V is the volume of the capacitor (not its voltage). Part F A parallel-plate capacitor has area A and plate separation d, and it is charged so that the electric field inside is E. Use the formulas from the problem introduction to find the energy U of the capacitor. Express your answer in terms of A, d, E, and appropriate constants. View Available Hint(s) AEQ U = Submit Part G Find the energy density u of the electric field in a parallel-plate capacitor. The magnitude of the electric field inside the capacitor is E. Express your answer in terms of E and appropriate constants. View Available Hint(s) u =