Also, if ? = -10-9C/m, R = 0.1 m, and ?0= pi/4, what is the x-component of the electric field (in N/C) at the point (x, y) = (0, 0)?
And, if ? = -10-9C/m, R = 0.1 m, and ?0= 45o, what is the direction of the electric field at the point (x, y) = (0, 0)? Give your answer in degrees measured counterclockwise from the positive x axis.
Also, if ? = -10-9C/m, R = 0.1 m, and ?0= pi/4, what is the x-component...
In a rectangular coordinate system a positive point charge q=6.00⋅10−9C is placed at the point x = +0.150 m, y = 0, and an identical point charge is placed at x = -0.150 m, y = 0. Find the x- and y-components, and the magnitude of the electric field at the origin.
A point charge of +10 micro-coulombs is placed at x = +0.2 m, y = 0 m and a point charge of -4 micro-coulombs is placed at x = 0 m, y = +0.38 m. What is the angle of the total electric field produced by both charges at the origin? In degrees measured counter-clockwise from the +x axis?
1. what is the electric field at the centre (r = 0) of a hemisphere bounded by r = a, 0 < θ < π/2 and 0 < φ < 2m, that carries a uniform volumetric charge density P3(The charges are distributed in this hemispherical 3D space. Use spherical coordinates due to the hemispherical geometry.) Consider some charges that are lined up in a straight line. This line of charge carries a uniform linear charge density. Let's make Pl =...
A spherical shell of radius R = 3 m has its center at the origin and carries a surface charge density of η = 3 nC/m^2. A point charge q = 250 nC is on the y-axis at y = 2 m. 17.1 Determine the electric field on the x-axis at x = 2 m. Leave your answer in component form. 17.2 Determine the electric field on the x-axis at x = 4 m. Leave your answer in component form
1.A point charge of +6 micro-coulombs is placed at x = +0.21 m, y = 0 m and a point charge of -3 micro-coulombs is placed at x = 0 m, y = +0.57 m. What is the angle of the total electric field produced by both charges at the origin? In degrees measured counter-clockwise from the +x axis? 2.A point charge of +5 micro-coulombs is placed at x = +0.4 m, y = 0 m and a point charge...
2. A thin ring of radius R in the x - y plane is centered at the coordinate origin, and is charged with linear charge density λ which depends* on the polar angle θ as (9) λο sin(0), where 0 > 0, and θ . (a) Plot λ(0) for θ [0.2n]. (b) Before doing any calculations, sketch the electric field vector vector at the coor- - 0 is on the positive r-axis dinate origin in the direction you expect it...
A 2.20 10-9 C charge has
coordinates x = 0, y = −2.00; a 3.18 10-9 C charge has coordinates
x = 3.00, y = 0; and a -4.95 10-9 C charge has coordinates x =
3.00, y = 4.00, where all distances are in cm. Determine magnitude
and direction for the electric field at the origin and the
instantaneous acceleration of a proton placed at the origin.
A 2.20 × 10-9C charge has coordinates x = 0, y =-2.00;...
a circular ring of charge of radius 1 m lies in the x-y plane and is centered at the origin. Assume also that the ring is in air and carries a density 2rho C/m. A) find the electric potential V AT (0,0,Z) b) Find the corresponding electric field E. (Assume electric field @point have x,y direction because Rho(l) is not constant)
Two very long concentric cylindrical shells of radii r=0.05 m and R=0.1 m are located in air. The inner shell carries a uniformly distributed positive charge of linear density 2 nC/m. The outer shell carries a uniformly distributed negative charge of linear density -2 nC/m. Apply Gauss' Law to find the expression of the electric field at a point located at a distance x from the common axis, where r<x<R. Describe the chosen Gaussian surface.
A point charge of +9 micro-coulombs is placed at x = +0.44 m, y = 0 m and a point charge of -2 micro-coulombs is placed at x = 0 m, y = +0.58 m. What is the angle of the total electric field produced by both charges at the origin? In degrees measured counter-clockwise from the +x axis?