# Chapter-23 - 945 Chapter 23 1 The vector area r A and the...

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Unformatted text preview: 945 Chapter 23 1. The vector area r A and the electric field r E are shown on the diagram below. The angle θ between them is 180° – 35° = 145°, so the electric flux through the area is ( 29 ( 29 2 3 2 2 cos 1800 N C 3.2 10 m cos145 1.5 10 N m C. E A EA θ-- Φ = ⋅ = = × ° = - × ⋅ r r 2. We use Φ = z ⋅ r r E dA and note that the side length of the cube is (3.0 m–1.0 m) = 2.0 m. (a) On the top face of the cube y = 2.0 m and ( 29 ˆ j dA dA = r . Therefore, we have ( 29 ( 29 2 ? ? 4i 3 2.0 2 j 4i 18j E =- + =- r . Thus the flux is ( 29 ( 29 ( 29( 29 2 2 2 top top top ? ? 4i 18j j 18 18 2.0 N m C 72 N m C. E dA dA dA Φ = ⋅ =- ⋅ = - = - ⋅ = - ⋅ ∫ ∫ ∫ r r (b) On the bottom face of the cube y = 0 and dA dA r =- b g e j \$ j . Therefore, we have E =- + =- 4 3 0 2 4 6 2 \$ \$ \$ \$ i j i j c h . Thus, the flux is ( 29 ( 29 ( 29 ( 29 2 2 2 bottom bottom bottom ? ? 4i 6j j 6 6 2.0 N m C 24 N m C. E dA dA dA Φ = ⋅ =- ⋅- = = ⋅ = + ⋅ ∫ ∫ ∫ r r (c) On the left face of the cube ( 29 ( 29 ˆ i dA dA =- r . So ( 29 ( 29 ( 29 ( 29 2 2 2 left left bottom ? ? ˆ 4i j i 4 4 2.0 N m C 16 N m C. y E dA E dA dA Φ = ⋅ = + ⋅- = - = - ⋅ = - ⋅ ∫ ∫ ∫ r (d) On the back face of the cube ( 29 ( 29 ˆ k dA dA =- r . But since E r has no z component E dA ⋅ = r r . Thus, Φ = 0. CHAPTER 23 946 (e) We now have to add the flux through all six faces. One can easily verify that the flux through the front face is zero, while that through the right face is the opposite of that through the left one, or +16 N·m 2 /C. Thus the net flux through the cube is Φ = (–72 + 24 – 16 + 0 + 0 + 16) N·m 2 /C = – 48 N·m 2 /C. 3. We use Φ = ⋅ r r E A , where r A A = = \$ . \$ j m j 2 140 b g . (a) ( 29 ( 29 2 ? 6.00 N C i 1.40 m j 0. Φ = ⋅ = (b) ( 29 ( 29 2 2 ? 2.00 N C j 1.40 m j 3.92 N m C. Φ = - ⋅ = - ⋅ (c) ( 29 ( 29 ( 29 2 ? ? 3.00 N C i 400 N C k 1.40 m j   Φ =- + ⋅ =   . (d) The total flux of a uniform field through a closed surface is always zero. 4. There is no flux through the sides, so we have two “inward” contributions to the flux, one from the top (of magnitude (34)(3.0) 2 ) and one from the bottom (of magnitude (20)(3.0) 2 ). With “inward” flux being negative, the result is Φ = – 486 N ⋅ m 2 /C. Gauss’ law then leads to 12 2 2 2 9 enc (8.85 10 C /N m )( 486 N m C) 4.3 10 C. q ε-- = Φ = × ⋅- ⋅ = - × 5. We use Gauss’ law: q ε Φ = , where Φ is the total flux through the cube surface and q is the net charge inside the cube. Thus, 6 5 2 12 2 2 1.8 10 C 2.0 10 N m C. 8.85 10 C N m q ε-- × Φ = = = × ⋅ × ⋅ 6. The flux through the flat surface encircled by the rim is given by 2 . a E Φ = π Thus, the flux through the netting is 2 3 4 2 (0.11 m) (3.0 10 N/C) 1.1 10 N m /C a E π π 2-- ′ Φ = -Φ = - = - × = - × ⋅ ....
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## This note was uploaded on 08/09/2010 for the course PHY 202 101A2 taught by Professor Prof.yang during the Summer '10 term at National Taiwan University.

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Chapter-23 - 945 Chapter 23 1 The vector area r A and the...

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