1 / 23

Electric Potential

Electric Potential. A. GPE = mgΔh. GPE = mgh A – mgh B. F = mg. GPE = Work (W) required to raise or lower the book. - Where W = (F gravity )( Δh). B. h A. h B. Gravitational Potential Energy. + + + + + + + + +. ΔPE e = q o EΔd.

selma
Download Presentation

Electric Potential

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Electric Potential

  2. A GPE = mgΔh GPE = mghA – mghB F = mg • GPE = Work (W) required to raise or lower the book. • -Where W = (Fgravity)(Δh) B hA hB Gravitational Potential Energy

  3. + + + + + + + + + ΔPEe = qoEΔd ΔPEe = qoEdA – qoEdB dA -WE(AB) = qoEdA – qoEdB A B + + -WE(AB) = FedA – FedB dB Fe = qoE Fe = qoE - - - - - - - - - - Electric Potential Energy • Does a proton at rest at point A have more or less potential energy than it would at point B? More

  4. F F +q -qo F F +q +qo Electric Potential Energy of Point Charges and Work • Much like the book is attracted to the earth due to gravity, two unlike charges are attracted to one another. • Conversely, like charges repel. • It takes positive work to move unlike charges away from one another and like charges closer together.

  5. -qo +q Electric Potential Energy • What would happen if the charged particle q was fixed in place and then particle qo was suddenly released from rest? • It would accelerate away from q. • It would accelerate towards q. • It would stay where it is. • How would the potential energy of this system change? • It would increase. • It would decrease. • It would remain the same.

  6. Electric Potential SI Units: joule/coulomb = 1 volt (V) • The Electric Potential Difference is equal to the Work required to move a test charge from infinity to a point in an electric field divided by the magnitude of the test charge. • The Electric Potential is the energy per unit of charge (J/C).

  7. Example 1: Electric Potential • An object with 2.5C of charge requires 1.00x10-3 Joules of energy to move it through an electric field. What is the potential difference through which the charge is moved?

  8. + + + + + + + + + + + ++++ - - - - - - - - - - - ---- qo B Uniform Electric Field Two equal and oppositely charged plates qo C qo A Characteristics of a Capacitor E • Since the electric field is constant, the force acting on a charged particle will be the same everywhere between the plates. • Fe = qoE FA = FB = FC

  9. + + + + + + + + + + + ++++ - - - - - - - - - - - ---- B F = qoE dB dA qo Electric Potential and Work in a Capacitor D WAB = F·dB - F·dA A qo WAB = qoEd F = qoE (PEe) -WAB qo qo V = = qo C If WAB = qoEd, then what is WCD? • WCD = 0 Joules because the force acts perpendicular to the direction of motion. • Do you remember that W = F·d·cos?

  10. + + + + + + + + + + + ++++ - - - - - - - - - - - ---- d Electric Potential of a Capacitor – An alternative • From mechanics, W = Fd. • From the previous slide, W = qoEd • From the reference table, V = W/qo Two equal and oppositely charged plates A B qo F = qoE Uniform Electric Field

  11. d Example 2:Parallel Plates A spark plug in an automobile engine consists of two metal conductors that are separated by a distance of 0.50 mm. When an electric spark jumps between them, the magnitude of the electric field is 4.8 x 107 V/m. What is the magnitude of the potential difference V between the conductors? V = Ed V = (4.8 x 107 V/m)(5.0 x 10-4m) V = 24,000V

  12. Example 3: Parallel Plates A proton and an electron are released from rest from a similarly charged plate of a capacitor. The electric potential is 100,000 V and the distance between the two plates is 0.10 mm. • Which charge will have greater kinetic energy at the moment it reaches the opposite plate? • Determine the amount of work done on each particle. • Determine the speed of each particle at the moment it reaches the opposite plate. • Determine the magnitude of the force acting on each particle. • Determine the magnitude of the acceleration of each particle.

  13. + + + + + + + + + + + ++++ - - - - - - - - - - - ---- d Example 3: Parallel Plates(cont.) • Begin by drawing a picture and listing what is known: • V = 100,000V • d = 0.10 mm = 1.0 x 10-4m • qe = qp = 1.6 x 10-19C (ignore the sign. We are only interested in magnitude.) p+ e-

  14. Example 3: Parallel Plates(#1 & #2) • For #1, you could answer #2 first to verify. • The answer is that the kinetic energy of both particles will be the same • Why? • because of the formula needed in question #2 applies to both charges, and work = energy. • Hence: Wproton = Welectron qprotonV = qelectronV Wproton = Welectron = (1.6x10-19C)(100,000V) Wproton = Welectron = 1.6x10-14 J

  15. Example 3: Parallel Plates(#3) • Apply the work-energy theorem to determine the final speed of the electron and proton. W = KE • Since the initial kinetic energy is equal to 0J: W = KEf W = ½ mvf2 • Proton: • Electron:

  16. Example 3: Parallel Plates(#4) • Since F = qE, it will be the same for both particles because their charges are the same and the electric field is uniform between two parallel plates. • We also know that W = Fd. Since we know the distance between the plates and the work done to move either charge from one plate to another, we can determine the force as follows:

  17. Example 3: Parallel Plates(#5) • Since we have the force acting on each particle, we can now calculate the acceleration of each particle using Newton’s 2nd Law.

  18. Equipotential Lines • Equipotential lines denote where the electric potential is the same in an electric field. • The potential is the same anywhere on an equipotential surface a distance r from a point charge, or d from a plate. • No work is done to move a charge along an equipotential surface. Hence VB = VA (The electric potential difference does not depend on the path taken from A to B). • Electric field lines and equipotential lines cross at right angles and point in the direction of decreasing potential.

  19. + + + + + + + + + + + ++++ - - - - - - - - - - - ---- Lines of Equipotential Note: Electric field lines and lines of equipotential intersect at right angles. Equipotential Lines • Parallel Plate Capacitor Electric Field Lines Decreasing Electric Potential / Voltage

  20. Note: Electric field lines and lines of equipotential intersect at right angles. Lines of Equipotential + Equipotential Lines • Point Charge Electric Field Lines Note: A charged surface is also an equipotential surface! Decreasing Electric Potential / Voltage

  21. Equipotential Lines (Examples) • http://www.cco.caltech.edu/~phys1/java/phys1/EField/EField.html

  22. Key Ideas • Electric potential energy (U) is the work required to bring a positive unit charge from infinity to a point in an electric field. • Electric potential (V) is the change in energy per unit charge as the charge is brought from one point to another. • The electric field between two charged plates is constant meaning that the force is constant between them as well. • The electric potential between two points is not dependent on the path taken to get there. • Electric field lines and lines of equipotential intersect at right angles.

  23. + + + + + + + + + + + ++++ - - - - - - - - - - - ---- B F = qoE dB dA qo Electric Potential Energy and Work in a Uniform Electric Field A qo F = qoE Note: The force acting on the charge is constant as it moves from one plate to another because the electric field is uniform. WAB = EPEB – EPEA WAB = FdB – FdA WAB = qoEdB – qoEdA WAB = qoE(dB – dA) = qoEd

More Related