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4: Potential and Field Relationships

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    • 4.1: Electric Potential from Electric Field
      The electric potential is different from the electric field, but the two quantities are related.  In this section, we learn how to calculate the electric potential change along a path between two points from the electric field in that region of space.
    • 4.2: Electric Field from Electric Potential
      In certain systems, we can calculate the potential by integrating over the electric field. As you may already suspect, this means that we may calculate the electric field by taking derivatives of the potential, although going from a scalar to a vector quantity introduces some interesting wrinkles. We frequently need E to calculate the force in a system; since it is often simpler to calculate the potential directly, there are systems in which it is useful to calculate V and then derive E.
    • 4.3: Equipotential Curves and Surfaces
      We can represent electric potentials pictorially, just as we drew pictures to illustrate electric fields. This is not surprising, since the two concepts are related. We use arrows to represent the magnitude and direction of the electric field, and we use green lines to represent places where the electric potential is constant. These are called equipotential surfaces in three dimensions, or equipotential lines in two dimensions.
    • 4.4: Conductors in Electrostatic Equilibrium
      When charges are stationary in a conductor, it is in a state of electrostatic equilbrium.  This section describes the properties of conductors in electrostatic equilibrium in regard to the electric field, electric potential, and surface charge density both inside and on the surface of the conductor.
    • 4.5: Applications of Electric Potential and Conductors in Electrostatic Equilibrium
      This section describes some practical applications of conductors including grounding and bonding, lightning rods, and electrical screening (Faraday cage), and their implications for electrical safety.
    • 4.6: Potential and Field Relationships (Summary)
    • 4.7: Potential and Field Relationships (Exercises)
    • 4.8: Potential and Field Relationships (Answers)

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