An infinite sheet of charge, orientedperpendicular to the x-axis, passes through x =3 μC/m2.0. It has a surface charge density o1 =A thick, infinite conducting slab, also orientedperpendicular to the x-axis, occupies the regionbetween a = 2.6 cm and b = 4.6 cm. Theconducting slab has a net charge per unit area of02 = 78 µC/m2. (Recall that the surface chargedensities oa and oh on the slab surfaces at a andb, respectively, sum to equal the net charge perunit area: oa + ob = 02.)1) What is Ex(P), the value of the x-component of the electric field at point P, locateda distance 7.8 cm from the infinite sheet of charge?N/C Submit2) What is Ey(P), the value of the y-component of the electric field at point P, locateda distance 7.8 cm from the infinite sheet of charge?N/C Submit+3) What is Ex(R), the value of the x-component of the electric field at point R, locateda distance 1.3 cm from the infinite sheet of charge?N/C Submit4) What is Ey(R), the value of the y-component of the electric field at point R, locateda distance 1.3 cm from the infinite sheet of charge?N/C Submit5) What is ob, the charge per unit area on thesurface of the slab located at x = 4.6 cm?| µC/m²Submit6) What is Ex, the value of the x-component of the electric field at a point on the x-axis located at x = 3.4 cm ?N/C Submit+7) What is oa, the charge per unit area on the surface of the slab located at x = 2.6cm?µC/m2Submit

Given, The charge density of the sheet is -3 The charge density of the thick sheet is 78 the charge…

Answered: An infinite sheet of charge, oriented…

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