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Transcript
Electric Field of a point charge - Electric Field lines of a point charge + Electric Dipoles An electric dipole consists of two charges Q, equal in magnitude and opposite in sign, separated by a distance β. The dipole moment, π β‘ πΈβ, points from the negative to the positive charge. Electric Dipoles An electric dipole in a uniform electric field will experience no net force, but it will, in general, experience a torque: Electric Dipoles The electric field created by a dipole is the sum of the fields created by the two charges; far from the dipole, the field shows a 1/r3 dependence: Extra Credit Problem If the earth's electric field is 100 N/C downward, what must be the charge on a 1-kg object so that it would be "weightless"? A) 1.0 C B) 0.22 C C) -9.8 ×10-2 C D) 9.8 C E) 9.8 × 10-2 C Gaussβs Law Electric Flux Electric flux: Ξ¦E = πΈβ₯ π΄ = πΈπ΄β₯ = πΈπ΄πππ π Ξ¦E = πΈ β π΄ Uniform E-field Electric flux through an area is proportional to the total number of field lines crossing the area. Calculate the electric flux through the rectangle shown. The rectangle is 10 cm by 20 cm, the electric field is uniform at 200 N/C, and the angle ΞΈ is 30°. a) b) c) d) e) ππ ππ΅β πͺ π π ππ π΅ β πͺ π π π. π π΅ β πͺ π π π. π π΅ β πͺ π΅πππ πππ πππππππ Electric Flux Uniform E-field: Ξ¦E = πΈβ₯ π΄ = πΈπ΄β₯ = πΈπ΄πππ π Ξ¦E = πΈ β π΄ Arbitrary E-field: π½π = π¬ β π π¨ Flux through a closed surface: Gaussβs Law The net number of field lines through the surface is proportional to the charge enclosed, and also to the flux, giving Gaussβs law: This can be used to find the electric field in situations with a high degree of symmetry. Example For a point charge, Therefore, Solving for E gives the result we expect from Coulombβs law: Using Coulombβs law to evaluate the integral of the field of a point charge over the surface of a sphere surrounding the charge gives: π¬ β π π¨ = πΈ πΈ π πΈ π ππ π = π π¨ = π π ππ ππ π ππ ππ ππ π Looking at the arbitrarily shaped surface A2, we see that the same flux passes through it as passes through A1. Therefore, this result should be valid for any closed surface. Finally, if a gaussian surface encloses several point charges, the superposition principle shows that: Therefore, Gaussβs law is valid for any charge distribution. Note, however, that it only refers to the field due to charges within the gaussian surface β charges outside the surface will also create fields. Consider the two gaussian surfaces, A1 and A2, as shown. The only charge present is the charge Q at the center of surface A1. What is the net flux through A2? a) 0 b) Not 0 c) Cannot tell with given information. A thin spherical shell of radius r0 possesses a total net charge Q that is uniformly distributed on it. Determine the electric field at points (a) outside the shell, and (b) within the shell. (c) What if the conductor were a solid sphere? Solid sphere of charge. An electric charge Q is distributed uniformly throughout a non-conducting sphere of radius r0. Determine the electric field (a) outside the sphere (r > r0) and (b) inside the sphere (r < r0).
