A positive charge (+e) is located at a position (0,-d/2, 0) and a negative charge (-e) islocated at another position (+d/2, 0, 0) in space respectively. Assume an isolatedpositive test charge (+1 C) is placed at the origin O(0,0).(a) Sketch the charge distribution of the network in graph up-to the scale.(b) Determine the magnitude and direction of the net Coulomb force exerted on the testcharge at the origin by the network of opposite charges (+e, -e) separated at 5.0 cm.(c) Determine the magnitude and direction of the total Electric Field Intensity (E)experienced by the test charge at the origin due to the opposite charges (+e, -e)placed at 5.0 cm apart.

a. The charge distribution is as shown in the graph below:

Answered: A positive charge (+e) is located at a…

Similar questions

A charge q with mass m has a velocity v far away. A small metallic loop of area A and resistance R is fixed and oriented such, that it and the vector v are in the same plane. The impact parameter of the charge with respect to the loop is h. Assuming that h>>R, there is not gravity and air resistance, find the velocity (magnitude and direction) of the charge after a very long time.
In your copper electrode experiment you measure a total charge transferred as 116.5 C. Determine the theoretical mass transferred (use four significant figures).
A parrallel plate capacitor has circular cross-section with a radius R and has a charge that varias Q(t). Take the spacing between the plates to be small so that you can assume the electric field is uniform for r < R and vanishes for r>R. Answer in terms of Q(t) and its derivatives.(a) What is the magnitude of the electric field inside the capacitor as a function of time? (b) Inside the capacitor (for r<R), what is the magnetic field as a fucntion of time at a distance r from the center? Use Ampere-Maxwel law with displacement current.
A dielectric rod with cross-section area of A and polarization of Px = ax² + b is extended from x = 0 to x = L. (a) Calculate the bound volume charge density and bound surface charge density. b) Determine the total bound charge.
Please answer the following question(s): 1. When a battery is connected to a capacitor (device that stores charge) the charge q builds up -t according to the equation q = q (1-e ¹), where do is the maximum charge and ī is a constant. At what time t does the charge reach 10% of its maximum value? (Note: Enter your answer in terms of tau, ī, using the Greek letters in MathType.) √ S t10% =
The diagram below depicts a cross section of coaxial conductor with an inner wire of diameter di and an outer conducting sheath of inside diameter do, and some material placed in the space between the two wires. Suppose that you have a coaxial wire with di=1.3 mm and do=7.55 mm, and we put mylar (κ=3.1) in the space between the two wires. If there is a potential of 1 kV between the wires, how much energy is stored in a 10 m piece of cable? For my answer I got 5.32 J which was wrong.
Suppose a van e Graff generator builds a negative static charge and grounded conductor is placed near enough to it so that a 7.0 x 10^6 coulombs of negative charge arcs to the conductor. Can you help me to conceptualize the steps in calculating the number of electrons that are transferred?
For problem 4 part b in square centimeters using inner and outer radii of the spherical capacitor of a = 2.00 cm and b = 1.05 a, respectively. (Answer in 5 sig. figs.)
You Answered Correct Answer A line of charge is placed along the negative x axis from x=-0.4m to x=0. The charge is uniformly distributed with linear charge density 3.06pC/m. A proton is released from rest at a point on the positive x axis 2.53m. When the proton has a speed of 472.1m/s, how far will it have moved (in m}? 1.0975 margin of error +/-1%
Needs Complete typed solution with 100 % accuracy.