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Phy 203: General Physics III Ch 19: Electric Potential Energy & the Electric Potential Lecture Notes.

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Presentation on theme: "Phy 203: General Physics III Ch 19: Electric Potential Energy & the Electric Potential Lecture Notes."— Presentation transcript:

1 Phy 203: General Physics III Ch 19: Electric Potential Energy & the Electric Potential Lecture Notes

2 Electric Potential Energy When charge is in an electric field, the electric force exerted upon it, as it moves from one point (A) to another point (B) can do work: W AB =F E.  s. cos  This only works when the applied force (F E ) is constant! When FE is not constant, the work performed is equal to the difference in electric potential energy (EPE): W AB =EPE A -EPE B Note: EPE is similar to gravitational PE (PE grav ) –it is the energy associated to the position of an object subject to an electric force –units are joules (J)

3 Electric Potential the electric potential (V) is the electric potential energy per unit charge: V=EPE/q –in this manner, V associated with a position can be expressed without concern for the specific charge present –the SI units are joules/coulomb (J/C), called the volt (V) the work performed on an electric charge is related to the change in electric potential (  V) and its charge (q): -W AB =q.  V or  V = -W AB /q Since F E =qE and W AB = F E.  s we can combine them to obtain: E = -  V/  s

4 Alessandro Volta (1745-1827) Italian physicist & inventor First person to isolate methane Fascinated with electricity at an early age Pioneered the field of electrochemistry constructed the first battery to produce electricity (called a voltaic pile)

5 Electric Potential (for a point charge) The E field for a point charge is The work required to bring a “test” charge (q o ) from “infinity” to a position r is W = EPE r  – EPE  = EPE r {since EPE  = 0} The EPE is related to F E and r: The electric potential (V) at r then becomes:

6 Capacitors & Dielectrics The electric field (E) within the plates of a capacitor is constant but the electric potential (V) is not The electric potential (V) is higher at the positive charged plate (+q) and lower at the negative charged plate (-q)  V = - E.  s where  s is the plate separation As the capacitor is charged, the charge that builds up at each plate is proportional to the potential difference across the plates Q ~  V The capacitance (C) is defined as as the ratio: C = Q/  V (or Q/V where one of the plates is V o =0V)

7 Capacitors & Dielectrics For a parallel plate capacitor: C=   o A/d) Where –A is the surface area –d is the plate separation –K is the dielectric constant (E=E o ) Note: For vacuum or air-filled capacitor:  ~1 For other materials:  >1

8 Energy Stored in a Capacitor It takes work to charge a capacitor, that work is stored as electrical potential energy: The stored energy per unit volume (E/V) for a parallel plate capacitor is: (the Energy Density)

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