A Gaussian box is located in a region of space where there is a non-uniform electric electric field, as shown in the figure below. E₁ 2 TE h W L The box has a length of L=80cm, a width of w=68.9cm, and a height of h=17.7cm. The electric field has the following magnitudes at different locations in space: • At the right side of the box, the field has a magnitude of E₁ = 1483N/C • At the top, bottom, front, and back sides of the box, the field has a magnitude of E2 = 2845N/C • At the left side of the box, the field has a magnitude of E3 = 4595N/C What is the electric flux through the right side of the box? What is the electric flux through the top side of the box? What is the electric flux through the bottom side of the box? What is the electric flux through the front side of the box? What is the electric flux through the back side of the box? What is the electric flux through the left side of the box? What is the total charge enclosed by the Gaussian box? Upload your work. Browse... No file selected. Nm²/C Nm2/C Nm2/C Nm2/C Nm²/C Nm²/c nC

A Gaussian box is located in a region of space where there is a non-uniform electric electric field, as shown in the figure below. E₁ 2 TE h W L The box has a length of L=80cm, a width of w=68.9cm, and a height of h=17.7cm. The electric field has the following magnitudes at different locations in space: • At the right side of the box, the field has a magnitude of E₁ = 1483N/C • At the top, bottom, front, and back sides of the box, the field has a magnitude of E2 = 2845N/C • At the left side of the box, the field has a magnitude of E3 = 4595N/C What is the electric flux through the right side of the box? What is the electric flux through the top side of the box? What is the electric flux through the bottom side of the box? What is the electric flux through the front side of the box? What is the electric flux through the back side of the box? What is the electric flux through the left side of the box? What is the total charge enclosed by the Gaussian box? Upload your work. Browse... No file selected. Nm²/C Nm2/C Nm2/C Nm2/C Nm²/C Nm²/c nC

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter18: Electric Charge And Electric Field

Section: Chapter Questions

Problem 43PE: (a) Find the electric field at x = 5.00 cm in Figure 18.52 (a), given that q = 1.00 C. (b) at what...

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In which of the following contexts ran Gausss law not be readily applied to find the electric field? (a) near a long, uniformly charged wire (b) above a large, uniformly charged plane (c) inside a uniformly charged ball (d) outside a uniformly charged sphere (e) Gausss law can be readily applied to find the electric field in all these contexts.
(a) Find the electric field at x = 5.00 cm in Figure 18.52 (a), given that q = 1.00 C. (b) at what position between 3.00 and 8.00 cm is the total electric field the same as that for ? 2q alone? (c) Can the electric field be zero anywhere between 0.00 and 8.00 cm? (d) At very large positive or negative values of x, the electric field approaches zero in both (a) and (b). In which does it most rapidly approach zero and why? (e) At what position to the light of 11.0 cm is the total electric field zero, other than at infinity? (Hint: A graphing calculator can yield considerable insight in this problem.)
c) a) sheet for formula number) 6= Φ = d) e) ON.m²/C Problem 1 • Sphere-A of radius RA = 24 cm and a total charge QA = -7x10-⁹ [C]. Sphere-B of radius RB = 6 cm and a total charge QB = 6x10-⁹ [c]. ● b) ₁, the net electric flux through the spherical surface of radius r = 12 cm from the center of the spheres is given by Оф1= Оф1= (6-10-⁹) 8.85-10-12 spheres. E2 = f) B ON.m²/C -790.96 g) spheres? E3 = The net electric flux can be calculated using the formula number (refer to the formula The figure shows two concentric conducting thin spherical shells: Calculate 1. RB RA [SI unit] (-1.10-⁹) 8.85-10-12 OP₁ = [SI unit] What is the SI unit of the electric flux? ON/C ON/(C.m²) Calculate E2, the magnitude the electric field at r = 35 cm from the center of the (-7-10-⁹) 8.85-10-12 [SI unit] What is the SI unit of the electric field? ON/(C.m²) ON/C Calculate E3, the magnitude of the electric field at r = 5 cm from the center of the
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A vertical electric field of magnitude 2.55 × 10* N/C exists above the Earth's surface on a day when a thunderstorm is brewing. A car with a rectangular size of 6.00 m by 3.00 m is traveling along a dry gravel roadway sloping downward at 17.4°. Determine the electric flux through the bottom of the car. N•m?/c
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A hollow metal sphere has 7 cm and 9 cm inner and outer radii, respectively, with a point charge at its center. The surface charge density on the inside surface is –250 nC/m² . The surface charge density on the exterior surface is +250 nC/m² . What is the strength of the electric field at point 12 cm from the center? Express your answer to three significant figures and include the appropriate units. • View Available Hint(s) HÀ ? a xa Xb b х-10п E Value N/C %3D
The picture shows the field lines of a nonuniform electric field and five points A to E in the field. Consider the following statements. Which • A B one is true? OThis electric field may be due to a negatively charged object E located to the left. The electric field strengths at points A and D are both zero because there are no electric field lines on them. OThe electric field strength at point C is larger than at point B. The electric field strength at point B is larger than at point C. The electric field strengths at points B and C are the same because they are on the same field line.
A V_ d B • +2o 2d 2d D. - The figure above shows three very thin parallel planes of charge with equal separation 12 cm between them. The charge density of the middle plane is +4 nC/m² (nC = "nano Coulomb") and that of the two outer planes is -2nC/m². Your answers for the electric field must include the correct sign. We choose positive electric field along the positive y-direction. What is the electric field at point A? N/C Submit Answer Tries 0/2 What is the electric field at point B? N/C Submit Answer Tries 0/2 What is the electric field at point C? N/C Submit Answer Tries 0/2 What is the electric field at point D? N/C 1
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A. Four closed surfaces, S₁ through S 4, together with the charges - 2Q, Q , and -Q are sketched in the Figure below. (The colored lines are the intersections of the surfaces with the page.) Find the electric flux through each surface. S₁ -20 SA B •+Q -2. S₂ Sz
Figure a -10 nC b 1 of 1 Part A What is the electric field at point 1 in (Figure 1)? Assume that a = 3.0 cm and b = 4.0 cm. Enter the x and y components of the electric field in newtons per coulomb separated by a comma. ▸ View Available Hint(s) Elx, Ely = Submit Part B E2x, E2y = Submit What is the electric field at point 2 in (Figure 1)? Enter the x and y components of the electric field in newtons per coulomb separated by a comma. ▸ View Available Hint(s) Part C H He E3x, E3y = Submit H He Be < Return to Assignment ?? What is the electric field at point 3 in (Figure 1)? Enter the and y components of the electric field in newtons per coulomb separated by a comma. ▸ View Available Hint(s) 6 4? Provide Feedback @= ?? N/C P Pearson N/C N/C