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Transcript
Andres La Rosa Portland State University Lecture Notes PH-212 ELECTRIC POTENTIAL-ENERGY (U) and the ELECTRIC POTENTIAL (V) U V in units of Joules in units of Joule/Coulomb = Volt Electric potential difference between two points A and B: VA - VB Interpretation of the electric potential-energy Consider an electric charge Q. The charge creates an electric field in the surrounding region Consider an electric test charge qo, which is initially located far away (at infinity) from the charge Q qo Q Point charge We want to bring qo from "infinity" to a place located at a distance r from Q Q Point qo charge Question: How much work does an external force Fext have to do to bring qo from infinity to a place located at a distance r from Q , at constant velocity? ds is the differential displacement vector qo Q Point charge Fext External force Electrical force Constant velocity implies: magnitude of the electrical force (Coulomb force ) = qo Q Point charge magnitude of the external force r Wext Magnitude of the external force Magnitude of the vector displacement Energy deposited by the external agent into the system formed by Q and qo , in order to place these two charges a distance r from each other. Wext Units of work: Joule Unit of U : Joule Electrical energy of this system is: qo Q Point r charge Notice the greater the charge qo the greater the U Definition of the electric potential V For the particular case of a point-charge Q, we have: Q Point charge r Electric potential established by the charge Q at the position P (located at a distance r from Q) is: General working procedure to obtain the electric potential: Checkpoints Positive POTENTIAL DIFFERENCE Given a charge Q, Electric potential at A Q Point charge VA = Electric potential at B Q Point charge VB = Definition VB - VA = Electrical potential difference between the points Bfinal and Ainitial In the example above, the path joining the points A and B was along the radial direction (with center at the charge q). It turns out that, for arbitrary locations of the points A and B, the potential difference VB -VA does not depend on the particular path that joins A and B. This is shown below. Particular path from A to B rB E r q Point charge dr rA εo rB rA C The result above indicates that the potential difference VB -VA does not depend on the particular path joining the points A and B. q The integral renders the same value whether we we choose path I, II, or III Relationship between the ELECTRIC POTENTIAL and the ELECTRIC FIELD Q Arbitrary charge distribution VB - VA = VB - VA = VB - VA = - E Electric-potential difference existent between the points B and A 1 4πε0 1 4πε0 1 4πε0 A A A A A A A A r1A r1A But notice r1A r2A r1A=r2A= r3A r3A V r
