1. An amount of positive charge Q is distributed uniformly along the positive x-axis from x=0 to x=a. A positive point charge is located on the x-axis at x=a+r. Calculate the magnitude of the net force that the charge distribution Q exerts on q
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2. A small 0.400g sphere carries a charge of 3.00*10^10C and is attached to one end of a silk fiber 8.00cm long. The other end of the fiber is attached to a large vertical insulating sheet that has a surface charge density equal to 25.0*10^-6C/m^2. The sphere on the end of the fiber is repelled outward and finally reaches a state of equilibrium. Find the angle that the fiber makes with the vertical sheet.
1. An amount of positive charge Q is distributed uniformly along the positive x-axis from x=0...
Positive charge Q is distributed uniformly along x-axis from
x=0
Positive charge Q is distributed uniformly along the x-axis from x = 0 to x = a. A positive point charge q is located on the positive x-axis at x = a + r, a distance r to the right of the end of Q (Fig. P21.89). Calculate the x- and y-components of the electric field produced by the charge distribution Q at points on the positive x-axis where x...
.1.Positive charge Q is distributed uniformly along the z-axis from x = 0 to x = a. A positive point charge q is located on he positive z-axis at a distance d to the right of the origin.(a) Calculate the electric potential produced by the charge distribution Q at x = d. (b) Develop an expression for the potential energy that would be added to the system by bringing a charge q from infinity to x = d. (c) Assuming the charges...
Positive charge Q is distributed uniformly along the positive y-axis between y = 0 and y = a. A negative point charge -q lies on the positive x-axis, a distance z from the origin (the figure (Figure 1))Part A Calculate the x-component of the electric field produced by the charge distribution Q at points on the positive x-axis. Part B Calculate the y-component of the electric field produced by the charge distribution Q at points on the positive y-axis.
A total charge of Q is uniformly distributed along the x-axis from x=0 to x=L. Find x-component of the electric field at x=0, y=a.
insulating sphere of radius a carries a positive charge 3Q, uniformly distributed its volume. Concentric with this sphere a conducting spherical shell with inner radius b and outer radius c, and having a net charge -Q as shown in Figure. Find the charge distribution on the shell (charge on the inner radius b and charge on the outer radius c) when entire system is in electrostatic equilibrium.
Why the E field due to point charge need to be negative?
Positive charge is distributed uniformly throughout an insulating sphere of radius R, centered at the origin. A particle with a positive charge is placed at x = 2R on the x axis. The magnitude of the electric field at x = R/2 on the x axis is: (62) 89 (A) 4NER2 QC) E ye B + 478, RP - 727€R? 81ER2 70 due to point) 1878 R2 charge...
A charge of Q is uniformly distributed along the semi-infinite x-axis with charge density 1.0 x 10^-6 Coulombs/m. Determine the electric field and the potential at the point (0, y).
A thin rod of uniformly distributed total charge Q lies along the x-axis, from x = 0 to x = a. What is the y-component of the electric field at a distance y along the y-axis (where y is not equals to 0)? Show all your workings from first principles
(22.63) Positive charge Q is distributed uniformly over each of two spherical volumes with radius R. One sphere of charge is centered at the origin and the other at x=2R as shown below. Find the magnitude and direction of the net electric field due to these two distributions of charge at the following points on the x-axis: a) x=0 b) x=R/2 c) x=R d) x=3R
A ring of radius a carries a uniformly distributed positive total charge Q. Calculate the electric field due to the ring at a point P lying a distance & from its center along the central axis perpendicular to the plane of the ring.