Tutorial-13-Electrostatic-potential key

How does it work?

Does understanding Electric Potential and Electric Potential Energy help to improve our idea on electricity? Why? How?

Directions: Solve for the given problems. Show your complete solutions. Round off your answers into 3 significant figures. 3. How far from a -6.4-µC point charge must a 1.8-µC point charge be placed for the electric potential energy to be equal to -0.350 J? 4. 1. A sphere centered at the origin has a radius of 0.200 m. A -4.20-µC charge is on the x-axis at x = 0.500 m. The net flux through the sphere is 400 N·m2/C. Calculate the total charge inside the sphere.

Directions: Solve the following problems. Show your complete solutions. Round off your answers into 3 significant figures.  3. A point charge q1 = 60.0 nC is held stationary at the origin. Another charge q2 = 40.0 nC is 30.0 cm away from the origin. What is the electric potential energy of the system?4. A point charge q1 is held stationary at the origin. A second charge q2 is placed at point a and the electric potential energy is 5.00 x 10^-8 J. When q2 was moved to point b, the electric force did -2.00 x 10^-8 J of work. What is the electric potential energy if q2 is at point b?

A graph of the electric field between two capacitor plates as a function of distance from the left plate is shown below. The distance between the plates is d, the direction of the field is to the right, and a battery is connected to the plates.   1. Which plate carries a positive charge? 2. How many slabs of material have been inserted between the plates? What is the thickness of the material in terms of d? 3. What can you say about the slab(s) inserted? 4. Sketch a graph of the electric field between the plates when the slabs between the plates are removed and the battery remains connected.   Useful information: C=QV=κC0 Cplates=ϵ0Ad Cspheres=4πϵ0R1R2R2−R1 Ccylinder=2πϵ0lln⁡(R2/R1)

Round your final answer with the correct number of significant digits

a. In an electron microscope, there is an electron gun that contains two charged metallic plates 3.10 cm apart. An electric force accelerates each electron in the beam from rest to 8.30% of the speed of light over this distance. (Ignore the effects of relativity in your calculations.) i. Determine the kinetic energy of the electron as it leaves the electron gun. Electrons carry this energy to a phosphorescent viewing screen where the microscope's image is formed, making it glow. ii. For an electron passing between the plates in the electron gun, determine the magnitude of the constant electric force acting on the electron. iii. Determine the acceleration of the electron. iv. Determine the time interval the electron spends between the plates.   b. A 0.26-kg stone is held 1.2 m above the top edge of a water well and then dropped into it. The well has a depth of 5.2 m. What is the change in gravitational potential energy of the system from release to reaching the bottom of the well?

a) A fish is 60 cm beneath the surface of a pond. An insect is flying directly overhead. If the insect is exactly 20 cm above the surface of water, how far above the surface does the insect appear to the fish? (Given: Refractive index of water = 1.33) b) An object and a screen separated by a distance of 72.0 cm. At what location(s) between the object and the screen should a convex lens of focal length 10.0 cm be placed so as to produce a clear image on the screen? c) A lens maker has to grind a convex lens with a focal length of 80.0 cm. The glass used for the lens has a refractive index, n = 1.5. If the radius of the curvature of the front surface is 35.0 cm, determine the radius of the other surface. d) Total internal reflection occurs when there is a difference of transparent medium density. Explain how total internal reflection take place and how can it be useful. |

The electric potential energy due to several point charges is given by the equation: U=kI qi/4. The r indicates: select the letter of your answer a the distance from the point charge b. the radius of the two pair of to the point at which the potential charges. energy is evaluated. c. the radius from the center of the d.none of the above charge