Kindly answer the last three subparts f, g &h of this question based on the passage in a clear handwriting with details. I am providing the full question because the whole question is related. kindly solve the questions following the given instructions of the question. d) Find the magnitude of electric field at point P2 and P3 due to solid sphere only.Magnitude of electric field at point P2Give your answer to at least three significance digits.N/CMagnitude of electric field at point P3Give your answer to at least three significance digits.N/CStep 3 Consider both the solid non-conducting sphere and infinite sheet for this stepe) Find the net flux through the Gaussian sphere of radius r.Flux through the Gassian surfaceGive your answer to at least three significance digits.N. m²/Cf) Net electric field at point P1x component of the electric fieldGive your answer to at least three significance digits.N/Cy component of the electric fieldGive your answer to at least three significance digits.N/Cg) Net electric field at point P2x component of the electric fieldGive your answer to at least three significance digits.N/Cy component of the electric fieldGive your answer to at least three significance digits.N/Ch) Net electric field at point P3x component of the electric fieldGive your answer to at least three significance digits.N/Cy component of the electric fieldGive your answer to at least three significance digits.N/C Use the following constants if necessary. Coulomb constant, k= 8.987 × 10 N · m² /C². vacuum permittivity, €o = 8.854 × 10¬12 F/m. Magnitudeof the Charge of one electron, e = -1.60217662 × 10¬19 C. Mass of one electron, me = 9.10938356 × 10¬31 kg. Unless specified otherwise, eachsymbol carries their usual meaning. For example, µC means micro coulomb.h!An infinite sheet lie on the xz plane and z axis points outward from the page (not shown). A solid non-conducting sphere of radius R is placed at h + rdistanceawayfrom the infinite sheet. Use the following values of these quantities charge density of sphere p = 32 pC/m³, charge density of the infinitsheet o = 34 pC /m² , radius of the solid sphere R = 4.5 m, radius of the Gaussian sphere r = 9.0 m value of h = 2.25 m. (here 1 pC means picocoulomb charge that is, 10-12C.)Step 1 Consider the infinite sheet only for this stepa) Find the magnitude of electric field at point Pq and P2 due to infinite sheet only. (Note: magnitude of a vector is a positive quantity.)Magnitude of electric field at point PGive your answer to at least three significance digits.N/CMagnitude of electric field at point P2Give your answer to at least three significance digits.N/Cb) Find the net flux through the Gaussian sphere of radius r due to infinite sheet only.Flux through the Gassian surfaceGive your answer to at least three significance digits.N- m² /CStep 2 Consider the solid non-conducting sphere only for this stepc) Find the net flux through the Gaussian sphere of radius r due to the solid sphere only.Flux thgourh the Gassian surfaceGive your answer to at least three significance digits.N- m² /C

Answered: Image /qna-images/answer/9be01186-76f2-4f9f-88a6-23566649b014.jpg

An infinite sheet lie on the xz plane and z axis points outward from the page (not shown). A solid non-conducting sphere of radius R is placed at h+1 distance away from the infinite sheet. Use the following values of these quantities charge density of sphere p = 32 pC /m³, charge density of the infinit sheet o = 34 pC/m² , radius of the solid sphere R = 4.5 m, radius of the Gaussian sphere r = 9.0 m value of h = 2.25 m. (here 1 pC means pico coulomb charge that is, 10-1²C.)

An infinite sheet lie on the xz plane and z axis points outward from the page (not shown). A solid non-conducting sphere of radius R is placed at h+1 distance away from the infinite sheet. Use the following values of these quantities charge density of sphere p = 32 pC /m³, charge density of the infinit sheet o = 34 pC/m² , radius of the solid sphere R = 4.5 m, radius of the Gaussian sphere r = 9.0 m value of h = 2.25 m. (here 1 pC means pico coulomb charge that is, 10-1²C.)

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter22: Magnetic Forces And Magnetic Fields

Section: Chapter Questions

Problem 5P

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Use the following constants if necessary. Coulomb constant, k = 8.987×10^9 N⋅ m^2/C^2 . Vacuum permittivity, ϵ0 = 8.854×10^−12 F/m . Magnitude of the Charge of one electron, e = −1.60217662×10^−19 C . Mass of one electron, me = 9.10938356×10^−31 kg . Unless specified otherwise, each symbol carries their usual meaning. For example, μC means microcoulomb .
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