@2WSAssignment Score:Question 9 of 15X# 3EThe figure shows a prism-shaped object that is 40.0 cm high,30.0 cm deep, and 80.0 cm long. The prism is immersed in auniform electric field of 700 N/C directed parallel to the x-axis.D>Calculate the electric flux D, out of Surface I (theback surface).Calculate the electric flux D₁ out of Surface II (thebottom surface).C83.3%Calculate the electric flux P out of Surface III (theleft end).Calculate the electric flux Dry out of Surface IV (theright end).ASA$4RFer s%5VFTG^6BMacBook ProYH&7NUJ* 00ResourcesMP₁ =Div =ФП = 0-Surface IP = 0K(9Ex Give Up?Surface III-224-X0O<hI)0LdP>.Feedback-:;Surface II{[?+ 1111ResumeIAttempt 1Surface IVSurface VN-m²/CN-m²/CN-m²/CN-m²/C}]deleteKreturnshift <@2Assignment Score: 83.3%Question 9 of 15 >WSX#3Calculate the electric flux P out of Surface III (theleft end).Calculate the electric flux Dy out of Surface IV (theright end).Calculate the electric flux py out of Surface V (thefront surface).ECalculate the net electric flux out of the entireclosed surface.DIf in addition to the given electric field the prism alsoenclosed a point charge of -2.00 μC, how wouldyour answers above change qualitatively, if at all?The electric flux out of each surface would increase.The electric flux out of each surface would decrease.O The electric flux through each surface wouldnot change.C$4RF%5V仪TGA6BMacBook ProCOYH➡))&7NU00 *8JResourcesPII = 0Φιν =Dy =MФ =Incorrect(900IncorrectK224C Give Up?0مهV)J0LP:38.;✓Feedback{[?+=11CIResumeAttempt 1N-m²/CN-m²/CN-m²/CN-m²/C}1delete>returnshift

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© Macmillan Learning The figure shows a prism-shaped object that is 40.0 cm high, 30.0 cm deep, and 80.0 cm long. The prism is immersed in a uniform electric field of 700 N/C directed parallel to the x-axis. Calculate the electric flux D, out of Surface I (the back surface). Calculate the electric flux P₁ out of Surface II (the bottom surface). Calculate the electric flux D out of Surface III (the left end). $₁ = P₁ = Surface I -X Surface III -224 0 h 0 Surface II Surface IV Surface V N-m²/C N-m²/C N-m²/C

© Macmillan Learning The figure shows a prism-shaped object that is 40.0 cm high, 30.0 cm deep, and 80.0 cm long. The prism is immersed in a uniform electric field of 700 N/C directed parallel to the x-axis. Calculate the electric flux D, out of Surface I (the back surface). Calculate the electric flux P₁ out of Surface II (the bottom surface). Calculate the electric flux D out of Surface III (the left end). $₁ = P₁ = Surface I -X Surface III -224 0 h 0 Surface II Surface IV Surface V N-m²/C N-m²/C N-m²/C

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter15: Electric Forces And Fields

Section: Chapter Questions

Problem 49P: Figure P15.49 shows a closed cylinder with cross-sectional area A = 2.00 m2. The constant electric...

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Suppose the electric field of Quick Quiz 15.7 is tilted 60 away from the positive z-direction. Calculate the magnitude of the flux through the same area. (a) 0 (b) 10.0 N m2/C (c) 20.0 N m2/C (d) More information is needed
Suppose the electric field of Quick Quiz 15.7 is tilted 60 away from the positive z-direction. Calculate the magnitude of the flux through the same area. (a) 0 (b) 10.0 N m2/C (c) 20.0 N m2/C (d) More information is needed
Figure P15.49 shows a closed cylinder with cross-sectional area A = 2.00 m2. The constant electric field E has magnitude 3.50 103 N/C and is directed vertically upward, perpendicular to the cylinder's top and bottom surfaces so that no field lines paw through the curved surface. Calculate the electric flux through the cylinder's (a) lop and (b) bottom surface, (c) Determine the amount of charge inside the cylinder. Figure P15.49
Figure P15.49 shows a closed cylinder with cross-sectional area A = 2.00 m2. The constant electric field E has magnitude 3.50 103 N/C and is directed vertically upward, perpendicular to the cylinder's top and bottom surfaces so that no field lines paw through the curved surface. Calculate the electric flux through the cylinder's (a) lop and (b) bottom surface, (c) Determine the amount of charge inside the cylinder. Figure P15.49
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A thin, square, conducting plate 50.0 cm on a side lies in the xy plane. A total charge of 4.00 108 C is placed on the plate. Find (a) the charge density on each face of the plate, (b) the electric field just above the plate, and (c) the electric field just below the plate. You may assume the charge density is uniform.
A cubical gaussian surface surrounds a long, straight, charged filament that passes perpendicularly through two opposite faces. No other charges are nearby. (i) Over how many of the cubes faces is the electric field zero? (a) 0 (b) 2 (c) 4 (d) 6 (ii) Through how many of the cubes faces is the electric flux zero? Choose from the same possibilities as in part (i).