1 / 36

Ch 26 – Capacitance and Dielectrics

Ch 26 – Capacitance and Dielectrics. The capacitor is the first major circuit component we’ll study…. Ch 26.1 – Capacitance. All conductors display some degree of capacitance . Usually, the term “ capacitor ” refers to two separate pieces of metal acting together.

tryna
Download Presentation

Ch 26 – Capacitance and Dielectrics

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. Ch 26 – Capacitance and Dielectrics The capacitor is the first major circuit component we’ll study…

  2. Ch 26.1 – Capacitance All conductors display some degree of capacitance. Usually, the term “capacitor” refers to two separate pieces of metal acting together. Each piece of metal is referred to as a plate.

  3. Ch 26.1 – Capacitance Electric field lines generated by a real parallel plate capacitor. Notice, the field is essentially uniform between the plates.

  4. Charging a capacitor: Fig 26-4b, p.800

  5. Charging a capacitor: Chemical potential energy maintains charge separation in the battery  the battery generates an E-field. Fig 26-4b, p.800

  6. Charging a capacitor: Chemical potential energy maintains charge separation in the battery  the battery generates an E-field. The battery’s E-field accelerates charges in the wires. Electrons flow off the orange plate and toward the blue plate. Fig 26-4b, p.800

  7. Charging a capacitor: Chemical potential energy maintains charge separation in the battery  the battery generates an E-field. The battery’s E-field accelerates charges in the wires. Electrons flow off the orange plate and toward the blue plate. Now, there is a charge imbalance across the capacitor’s plates. So… what must exist in between the plates of the capacitor? … an electric field. Fig 26-4b, p.800

  8. Charging a capacitor: Chemical potential energy maintains charge separation in the battery  the battery generates an E-field. The battery’s E-field accelerates charges in the wires. Electrons flow off the orange plate and toward the blue plate. Now, there is a charge imbalance across the capacitor’s plates. So… what must exist in between the plates of the capacitor? … an electric field. Charge continues to flow until the E-field in the capacitor is strong enough to cancel the E-field in the battery. Fig 26-4b, p.800

  9. Ch 26.1 – Capacitance A capacitor stores electrical potential energy by virtue of separating charges. The stored energy is “in” the capacitor’s E-field. Based on geometry and materials, some capacitors are better at storing energy than others.

  10. Ch 26.1 – Capacitance Called a capacitor because the device has some “capacity” to store electrical charge, given a particular applied potential difference (voltage). The ability of a capacitor to store charge given a certain applied voltage is called its “capacitance.”

  11. Ch 26.1 – Capacitance – factors affecting capacitance • Size of the capacitor (A, d) • Geometric arrangement • Plates • Cylinders • Material between conductors • Air • Paper • Wax

  12. Ch 26.1 – Capacitance The “capacitance,” C, of a capacitor is the ratio of the charge on either conductor to the potential difference between the conductors:

  13. Ch 26.1 – Capacitance Units: 1 F = 1 C/V The “farad” magnitude of charge on one plate voltage across the capacitor

  14. EG – Definition of Capacitance • How much charge is on each plate of a 4.00μF capacitor when it is connected to a 12.0-V battery? • If this same capacitor is connected to a 1.50-V battery, what charge is stored?

  15. Ch 26.2 – Parallel Plate Capacitors - one plate has +Q, the other -Q - for each plate σ = Q/A

  16. Ch 26.2 – Parallel Plate Capacitors - one plate has +Q, the other -Q - for each plate σ = Q/A - Gauss’s Law  the E-field just outside one of the plates

  17. Uniform E-field

  18. Ch 26.2 – Parallel Plate Capacitors Working backwards from the uniform E-field, the magnitude of the voltage between the plates is

  19. Ch 26.2 – Parallel Plate Capacitors Working backwards from the uniform E-field, the magnitude of the voltage between the plates is Capacitance of parallel plate capacitor   But:

  20. Ch 26.2 – Parallel Plate Capacitors Capacitance of parallel plate capacitor Capacitance of a parallel-plate capacitor is directly proportional to the area of the plates and inversely proportional to the distance between the plates. Think about:

  21. EG 26.1 – Cylindrical Capacitor A solid, cylindrical conductor of radius a and charge Q is coaxial with a cylindrical shell of negligible thickness, radius b>a, and charge –Q. Find the capacitance of this capacitor if its length is l.

  22. EG 26.2 – Spherical Capacitor A spherical capacitor consists of a spherical conducting shell of radius b and charge –Q concentric with a smaller conducting sphere of radius a and charge Q. Find the capacitance of this device.

  23. Ch 26.3 – Combinations of Capacitors Capacitors are intentionally used in circuits to alter the rates of change of voltages. Capacitors can be hooked up in two ways: - networked in parallel - networked in series

  24. Ch 26.3 – Combinations of Capacitors – parallel network • Connecting wires are conductors in electrostatic equilibrium  Ein =0 • Left plates at same electric potential as the positive terminal of the battery. • Right plates at same electric potential as the negative terminal of the battery. • Therefore, all capacitors in a parallel network experience the same potential difference, in this case, ΔV. ΔV1=ΔV2=ΔV ΔV

  25. Ch 26.3 – Combinations of Capacitors – parallel network The individual voltages across parallel capacitors are equal, and they are equal to the voltage applied across the network. ΔV1=ΔV2=ΔV ΔV

  26. Ch 26.3 – Combinations of Capacitors – parallel network • When battery is attached to circuit  capacitors quickly reach maximum charge, Q1 and Q2. •  total charge stored by the circuit is Qtot = Q1 + Q2. • So, for a given applied voltage, this network has some “capacity” to store charge. • In other words, the network itself can be thought of as a single capacitor, even though it has many components. ΔV1=ΔV2=ΔV ΔV

  27. Ch 26.3 – Combinations of Capacitors – parallel network • Let’s replace the two-capacitor network with a single equivalent capacitor that has capacitance Ceq. • Based on the definition of capacitance, Ceq = Qtot/ΔV. •  Qtot= CeqΔV • But, Qtot = Q1 + Q2, so  CeqΔV = C1ΔV1+ C2ΔV2 • In conclusion:  Ceq= C1+ C2 (parallel network) ΔV1=ΔV2=ΔV ΔV

  28. Ch 26.3 – Combinations of Capacitors – parallel network • In general, • Ceq= C1+ C2+… (parallel network) The equivalent capacitance of a parallel network is: -the algebraic sum of the individual capacitances -greater than any of the individual capacitances composing the network Ceq Qtot ΔV

  29. Ch 26.3 – Combinations of Capacitors – series network • Left plate of capacitor 1 is at same potential as positive terminal of the battery. • Right plate of capacitor 2 is at same potential as negative terminal of battery. • “Middle leg” has no net charge. ΔV

  30. Ch 26.3 – Combinations of Capacitors – series network • When battery is connected, electrons flow off the left plate of C1 and onto the right plate of C2. • Electrons accumulate on right plate of C2, establishing an electric field. • E-field forces electrons off the left plate of C2 and onto right plate of C1. • All right plates end up with –Q, and all left plates end up with +Q. ΔV

  31. Ch 26.3 – Combinations of Capacitors – series network ΔV2 ΔV1 • In other words, the magnitude of charge on all the plates is equal. • Q1 = Q2 = Q • Additionally, once the circuit reaches electrostatic equilibrium, the voltage across the network must cancel the battery’s voltage. • ΔVtot = ΔV1 + ΔV2 { { ΔV

  32. Ch 26.3 – Combinations of Capacitors – series network ΔV2 ΔV1 • This series network has some ability to store charge given an applied voltage, ie., it has some capacitance • In other words, even though the network has multiple components, it can be modeled using a single equivalent capacitor. • Lets build the same circuit using a single equivalent capacitor. { { ΔV

  33. Ch 26.3 – Combinations of Capacitors – series network ΔV2 ΔV1 Q1 = Q2 = Q (previous result) ΔVtot = ΔV1 + ΔV2 (previous result) From the definition of capacitance, ΔVtot = Q/Ceq Substituting for Δ Vtot, Q/Ceq = Q1/C1 + Q2/C2 Cancelling Q, 1/Ceq = 1/C1 + 1/C2 (series combination) { { ΔV

  34. Ch 26.3 – Combinations of Capacitors – series network Q1 = Q2 = Q (previous result) ΔVtot = ΔV1 + ΔV2 (previous result) From the definition of capacitance, ΔVtot = Q/Ceq Substituting for Δ Vtot, Q/Ceq = Q1/C1 + Q2/C2 Cancelling Q, 1/Ceq = 1/C1 + 1/C2 (series combination) ΔV { Ceq Q ΔV

  35. Ch 26.3 – Combinations of Capacitors – series network • In general, • 1/Ceq = 1/C1 + 1/C2 +… (series combination) • The inverse of the equivalent capacitance is the algebraic sum of the inverses of the individual capacitances. • The equivalent capacitance is always less than any individual capacitances in the network. ΔV { Ceq Q ΔV

  36. EG 26.3 – Equivalent Capacitance Find the equivalent capacitance between a and b for the combination of capacitors shown. All capacitances are in microfarads.

More Related