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Chapter 23 Electric Potential

Chapter 23 Electric Potential. Electric potential energy (sec. 23.1) Electric potential (sec. 23.2) Calculating elec. potential (sec. 23.3) Equipotential surfaces (sec. 23.4) Potential gradient (sec. 23.5). C 2012 J. Becker. Learning Goals - we will learn: ch 23

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Chapter 23 Electric Potential

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  1. Chapter 23 Electric Potential • Electric potential energy (sec. 23.1) • Electric potential (sec. 23.2) • Calculating elec. potential (sec. 23.3) • Equipotential surfaces (sec. 23.4) • Potential gradient (sec. 23.5) C 2012 J. Becker

  2. Learning Goals - we will learn: ch 23 • How to calculate the electric potential energy (U) of a collection of charges.• The definition and significance of electric potential (V).• How to use the electric potential to calculate the electric field (E).

  3. (a) When a positive charge moves in the direction of an electric field, the field does positive work and the potential energy decreases. Work = qo E d POSITIVE charge moving in an E field.

  4. The charge qo moves along a straight line extending radially from charge q.

  5. The work doneon charge qoby the electric field produced by charge q depends only on the distances ra and rb.

  6. Graphs of the potential energy U of two point charges q and q0 versus their separation r.

  7. The potential energy associated with a charge qo at point “a” depends on charges q1, q2, and q3 and on their distances r1, r2, and r3from point “a.”

  8. In both cases (positive or negative point charges), if you move qo in the direction of F, the electric potential V decreases; if you move qo in the direction opposite F, V increases. +qo Test charge Calculating the electric potential by integrating E.dl for a single point charge.

  9. Electric field E and potential V at points inside and outside a positively charged spherical conductor. E = dV / dr

  10. Find the potential V at point P on the axis of the ring. All charges in the ring (Q) are the same distance a from point P on the ring axis.

  11. Find the potential V at point P. Find the electric potential on the perpendicular bisector of a charged rod.

  12. Review See www.physics.sjsu.edu/becker/physics51 C 2012 J. F. Becker

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