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A. The vertical rectangular surface B. The slanted surface C. The entire surface of the box 3. Consider a thin, spherical shell of radius 12.0 cm with a surface charge density of 0.150 mC/m² distributed uniformly on its surface. Find the electric field: A. 7.0 cm B. 17.0 cm from the center of the charge distribution. 4. Four small spheres shown in the figure below have charges

A. The vertical rectangular surface B. The slanted surface C. The entire surface of the box 3. Consider a thin, spherical shell of radius 12.0 cm with a surface charge density of 0.150 mC/m² distributed uniformly on its surface. Find the electric field: A. 7.0 cm B. 17.0 cm from the center of the charge distribution. 4. Four small spheres shown in the figure below have charges

College Physics
College Physics
11th Edition
ISBN:9781305952300
Author:Raymond A. Serway, Chris Vuille
Publisher:Raymond A. Serway, Chris Vuille
Chapter1: Units, Trigonometry. And Vectors
Section: Chapter Questions
Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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PDF Activity 1.2 - Electric Flux and Ga x + O File | C:/Users/Danica%20Martinez/Desktop/Activity%201.2%20-%20Electric%20Flux%20and%20Gauss's%20Law(1).pdf +1 ... a Agoda G Gmail YouTube G Maps O Translate E MODULE 4.2 Electr. INSTRUCTIONS: Show your complete solution to each problem on a short bond paper. Answers must be expressed in engineering notation (when the exponent of the base 10 multiplier is not a multiple of 3, press ENG or SHIFT+ENG, whichever the case.) Example: 0.06N or 6.0x10-2 N must be expressed to 60x10-3 N or 60mN 1. A hemispherical surface with radiusr = 12 cm in a region of uniform electric field E = 10 V/m has its axis aligned parallel to the direction of the field. Calculate the flux through the surface. 2. In the figure shown, the magnitude of the uniform electric field is E = 70 kN/C. Calculate the electric flux through: 320 cm A. The vertical rectangular surface B. The slanted surface C. The entire surface of the box 45.0 cm 3. Consider a thin, spherical shell of radius 12.0 cm with a surface charge density of 0.150 mC/m2 distributed uniformly on its surface. Find the electric field: A. 7.0 cm B. 17.0 cm from the center of the charge distribution. 4. Four small spheres shown in the figure below have charges of g1 = -3.00 nC, q2 = 2.40 nC, g3 = 5.30 nC, and g4 = -1.80 nC. Find the net electric flux through each of the following closed surfaces: S2 S, A. S, B. S2 C. Sa D. S4 92 S4 5. The electric field at a distance of 0.35 m from a very long line charge is 1250 N/C. Calculate the total charge in a 6.00-cm section of such line. 11:07 am P Type here to search 32°C Haze A ENG 19/03/2022
Transcribed Image Text:PDF Activity 1.2 - Electric Flux and Ga x + O File | C:/Users/Danica%20Martinez/Desktop/Activity%201.2%20-%20Electric%20Flux%20and%20Gauss's%20Law(1).pdf +1 ... a Agoda G Gmail YouTube G Maps O Translate E MODULE 4.2 Electr. INSTRUCTIONS: Show your complete solution to each problem on a short bond paper. Answers must be expressed in engineering notation (when the exponent of the base 10 multiplier is not a multiple of 3, press ENG or SHIFT+ENG, whichever the case.) Example: 0.06N or 6.0x10-2 N must be expressed to 60x10-3 N or 60mN 1. A hemispherical surface with radiusr = 12 cm in a region of uniform electric field E = 10 V/m has its axis aligned parallel to the direction of the field. Calculate the flux through the surface. 2. In the figure shown, the magnitude of the uniform electric field is E = 70 kN/C. Calculate the electric flux through: 320 cm A. The vertical rectangular surface B. The slanted surface C. The entire surface of the box 45.0 cm 3. Consider a thin, spherical shell of radius 12.0 cm with a surface charge density of 0.150 mC/m2 distributed uniformly on its surface. Find the electric field: A. 7.0 cm B. 17.0 cm from the center of the charge distribution. 4. Four small spheres shown in the figure below have charges of g1 = -3.00 nC, q2 = 2.40 nC, g3 = 5.30 nC, and g4 = -1.80 nC. Find the net electric flux through each of the following closed surfaces: S2 S, A. S, B. S2 C. Sa D. S4 92 S4 5. The electric field at a distance of 0.35 m from a very long line charge is 1250 N/C. Calculate the total charge in a 6.00-cm section of such line. 11:07 am P Type here to search 32°C Haze A ENG 19/03/2022
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