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Chapter 9 Conductors and Dielectrics in Electrostatic Field

Chapter 9 Conductors and Dielectrics in Electrostatic Field. §9-1 Conductors 导体 Elecrostatic Induction 静电感应 . §9-2 Capacitance 电容器. §9-3 Dielectrics 电介质. §9-4 Gauss’ Law in Dielectric 有电介质时的高斯定律 Electric Displacement 电位移 . §9-5 Energy in Electric Field 电 场的能量.

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Chapter 9 Conductors and Dielectrics in Electrostatic Field

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  1. Chapter 9 Conductors and Dielectrics in Electrostatic Field

  2. §9-1 Conductors 导体 Elecrostatic Induction 静电感应 §9-2 Capacitance 电容器 §9-3 Dielectrics 电介质 §9-4 Gauss’ Law in Dielectric 有电介质时的高斯定律 Electric Displacement 电位移 §9-5 Energy in Electric Field 电场的能量

  3. § 9-1 Conductors and Electrostatic Induction can move in the conductor randomly e e e e e e e e Conductor: There are many free electrons in it.

  4. 1. The phenomena of the electrostatic induction The charges of an insulated conductor are redistributed because of external E-field.

  5. No external E-field The process of electrostatic induction of a conductor

  6. The process of electrostatic induction of a conductor external E-field is supplied--the electrons start to move.

  7. The process of electrostatic induction of a conductor induced external

  8. The process of electrostatic induction of a conductor induced external

  9. The process of electrostatic induction of a conductor induced external

  10. The process of electrostatic induction of a conductor induced external

  11. The process of electrostatic induction of a conductor induced external

  12. The process of electrostatic induction of a conductor induced external

  13. The process of electrostatic induction of a conductor induced external

  14. The process of electrostatic induction of a conductor induced external

  15. The process of electrostatic induction of a conductor induced external

  16. The process of electrostatic induction of a conductor induced external

  17. The process of electrostatic induction of a conductor 静电平衡状态

  18. 2. Electrostatic equilibrium (1). Electrostatic equilibrium state:There is no any charge moving along a definite direction macroscopically inside the conductor or on the surface of the conductor. The distribution of charges does not change with time. (2). Electrostatic equilibrium conditions:

  19. E=0 The behavior of E-field The E-field equals zero everywhere inside the conductor. The E-field at the surface of the conductor is perpendicular to the surface. The behavior of E-potential The conductor is an equipotential body. The conductor surface is an equipotential surface.

  20. Electrostatic field influences conductor: --electrostatic induction --make the charges in conductor redistribution. Conductor influences electrostatic field : -- make the electrostatic field redistribution. Example

  21. The field is uniform before the metal sphere is put in. E

  22. The field is no longer uniform after the metal sphere is put in. E + + + + + + +

  23. P--any point inside conductor, S--infinite small, No excess charge inside conductor. 3. The charge distribution on conductor at the electrostatic equilibrium state. (1). Entire conductor: No excess charges inside the conductor. They are found only on the conductor surface. Prove: Use S--any Gaussian surface inside conductor

  24. (2). A conductor with a cavity:Assume charged Q  No charge in the cavity: No charge inside and internal surface of the conductor. All the excess charges distribute on the outside surface of conductor. Prove: Draw a Gaussian surface S surrounding the cavity tightly.

  25. Inside the conductor Question?Are thereany equal magnitude and opposite sign charges on the internal surface of the conductor? i.e., --No net charge inside S Not at all.

  26. There are charges q in the cavity: On the inner surface of the conductor: --induction charges -q On the external surface of the conductor : The original charges Q of the conductor + induction charges +q

  27. Example: Two conducting spheres of different radii connected by a long conducting wire. 3.The relation about the charge distribution on the conductor surface and the its radius of curvature. They are equipotential.

  28. - - - - - - - - - - In a qualitative way, for a conductor of arbitrary shape, the charge density distribution on its surface is inverse proportional with its radius of curvature.

  29. . p 4. The relation about the E-field justoutside the conductor surface and the charge density on the conductor surface. is set up by all charges in the space (on and outside the conductor).

  30. + + + + + + - + + + Electrostatic generator candle 5. Application of electrostatic induction. (1).Tip discharge Lighting rod(避雷针) Electrostatic generator and electric wind (2).Electrostatic shielding

  31.  A conductor shell canshield the external field

  32.  Aconductor shell that is connected with the ground can shield the influence of the fields between inside and outside the conductor.

  33. The examples about electrostatic induction [Example 1]A neutral conductor sphere with radius R is put on the side of a point charge +q . Assume the distance between the spherical center and the point charge is d. Calculate:  The E-field and potential at point 0 set up by the induced charges on the sphere.If the sphere is connected with the ground, how much is the net charge on the sphere?

  34. Solution Assume the induction charges are±q  The total field at 0 = the field set up by q+ the field set up by ±q =0!!

  35. the potential at 0 set up by ±q: the potential at 0 set up by q :

  36.  the sphere is connected with ground. Assume net charge q1 is left on the sphere. the potential U0 at 0= Uq+Uq1

  37. QB QA σ1 σ2 σ3 σ4 [Example 2] Two large parallel plates with the area S carry charge Qa and QB respectively. Find:The charge and field distribution. solution Assume the charge surface density areσ1,σ2,σ3 andσ4 on the four surfaces .

  38. Ⅰ Ⅱ Draw a Gaussian surface at pointP:

  39. and

  40. Ⅰ Ⅱ E1 E1 E2 E2 E3 E3 E4 E4 The field distribution: E=0inside the plates outside the plates: direction: point to left  point to right  point to right 

  41. Ⅰ Ⅱ  Two plates carry equal magnitude and opposite sign charge discussion the charges distribute on the inner surface only. EⅠ= EⅢ= 0

  42. Ⅰ Ⅱ Two plates carry equal magnitude and same sign charge Charges distribute on the exterior surface only.

  43. [Example 3] conductor sphere with radius r1 carries +q and conductor spherical shell with inner and exterior radii r2 and r3 carries +Q.  Calculate theE distribution, the potential of sphere and shell U1 and U2, potential difference△U  Connect sphere and shell with a wire, find E, U1 and U2 ,△U =?. If the shell is connected with ground, findE, U1 , U2, △U =? If the sphere is connected with ground, find the charge distribution. U2=?

  44. solution : the field distribution:

  45. sphere potential:

  46. The shell potential: Potential difference:

  47.  Connect sphere and shell with a wire, All charges are on the exterior surface of the shell.

  48. U2=0,no any charge on the exterior surface of the shell. The shell is connected with ground,

  49. U1=0. Assume sphere chargesq',then the inner surface of shell charges -q',its exterior surface charges(Q+q')  The sphere is connected with ground,

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