A uniform linear charge density of 4.0 nC/m is distributed along the entire x-axis. Consider a spherical (radius = 5.0 cm) %3D surface centered on the origin. Determine the electric flux .through this surface (in N.m2/C) 45 68 23 79 62
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A: The charge enclosed by the surface can be calculated as follows,
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Q: A uniform charge density of 57 nC/m3 is distributed throughout a spherical volume (radius = 16.1…
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A: Disclaimer: Since you have uploaded a question with multiple sub-parts, we will solve the first…
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A: Total charge is Q = 9 × 10-9 C Radius of larger sphere is R = 12 mm Radius of smaller sphere is r…
Q: 1 #] F A solid conducting metal sphere of radius b and total charge -Q has an empty spherical cavity…
A: Explanation:Note : on the outer surface of cavity , charge enclosed is , -q , since , the field…
Q: 9.
A: Given that: a=3.00 cm=0.030 mb=2.00a=0.060 mc=2.40a=0.072 mq1=+5.10 fC=+5.10×10-15 Cq2=-q1=-5.10…
Q: In the figure a solid sphere of radius a = 3.20 cm is concentric with a spherical conducting shell…
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Q: The figure shows a spherical shell with uniform volume charge density ρ = 2.06 nC/m3, inner radius a…
A: Since you have uploaded a question with multiple sub-parts, we will solve the first three sub-parts…
Q: A hollow, conducting sphere with an outer radius of 0.260 m and an inner radius of 0.200 m has a…
A: Given that:R1=0.200 mR2=0.260 mσ=6.67×10-6 C/m2q=-0.500 μC=-0.500×10-6 C
Q: The figure below shows a solid conducting sphere with radius R = 7.00 cm. Upon inspection, the…
A: Solution Radius of the sphere is R=7.00 cm=0.070 m Distance of the point where the electric field is…
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A: Electric flux due to charge enclosed by a surface.
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Q: For a spherical surface with radius 0.14 m and is charged by 45 nC, the electric field E at r = 0.23…
A: Given: The radius (R) of the sphere is 0.14 m. The charge (Q) on the sphere is 45 nC. The distance…
Q: just g and h, please.
A: Solution:
Q: The figure shows a spherical shell with uniform volume charge density ρ = 2.06 nC/m3, inner radius a…
A:
Q: In the figure a solid sphere of radius a = 3.00 cm is concentric with a spherical conducting shell…
A: Given a = 3 cm B = 6 cm C = 7.2 cm
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Q: The figure shows two concentric thin spherical shells of radii ra = 3.09 cm and rb= 7.00 cm. If the…
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Q: Consider a thin, spherical shell of radius 12.0 cm with a surface charge density of 0.150 mC/m2…
A: according to Gauss's law ∮E·ds =Q∈0 where E is electric field ds small area for gaussian surface…
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Q: In the figure a solid sphere of radius a = 3.20 cm is concentric with a spherical conducting shell…
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Q: A uniform linear charge density of 60 nC/m is distributed along the entire x-axis. Consider a…
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A: Note: Out of given multiple parts, we solve only first three parts unless specified. You can resend…
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A: I have written formula
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A: Charge at centre, q = -3.80 μC = -3.80×10-6 CRadius, r = 6.50 cm = 0.065 metreDistance, d = 9.50 cm…
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