1). Fill in the data table for a single positive Charge. r (m) Electric Potential (...

A positive charge +Q is distributed uniformly throughout the volume of an insulating sphere with radius...

A positive charge +Q is distributed uniformly throughout the volume of an insulating sphere with radius R. Find the electric potential V at a point P a distance r from the center of the sphere. Plot the electric potential V vs. the distance r from the center of the sphere for 0 < r < 2R

The electric potential due to a point charge is given by V = k q /...

The electric potential due to a point charge is given by V = k q / r where q is the charge, r is the distance from q, and k =8.99×109Nm2⁄C2. A) Show, in detail, that the SI unit of electric potential is a volt. B) What are equipotential lines? C) How are equipotential lines used to obtain the electric field lines?

PART 1: THE ELECTRIC FIELD Procedure: Assemble in groups of 2-3 around the pod computers. You...

PART 1: THE ELECTRIC FIELD Procedure: Assemble in groups of 2-3 around the pod computers. You may also use a laptop or tablet. Open the Charges and Field simulation: http://phet.colorado.edu/en/simulation/charges-and-fields and click on the “play” symbol to open. Once the simulation opens, check the box next to grid. Your instructor will show you a few things about this simulation before you begin. Explore: Answer all questions and all parts below. 1. First, explore by placing a 1 nC positive charge...

Immediately outside a conducting sphere of unknown charge Q and radius R the electric potential is...

Immediately outside a conducting sphere of unknown charge Q and radius R the electric potential is 190 V, and 10.0 cm further from the sphere, the potential is 130 V. (a) Determine the radius R of the sphere (in cm). cm (b) Determine the charge Q on the sphere (in nC). nC (c) The electric potential immediately outside another charged conducting sphere is 220 V, and 10.0 cm farther from the center the magnitude of the electric field is 410...

1.Draw the equipotential lines for a single, positive, charge. 2. How can you tell from an...

1.Draw the equipotential lines for a single, positive, charge. 2. How can you tell from an electric field map whether an electric field is strong or weak? 3. What would the electric field lines look like if the electric field was constant? 4. Can there be a point in space where there is an electric potential but not electric field? Can there be a point in space where there is an electric field but no electric potential? Explain you answer.

Suppose that a negative charge distribution of in space presents the following expression for electric potential...

Suppose that a negative charge distribution of in space presents the following expression for electric potential as a function of radius: V(r)=-k*Q/(r^3-1) If the charge distribution Q = 1 C. The electrostatic force that a proton would feel (q = 1.6x10-19 C) at a 'r' of 1 x10-9 m distance is: (Use the relationship between electric potential and electric field, followed by the relationship between electric field and electrostatic force) Response options group F = + 4.315 x 10 ^...

An electric field has an electric field strength 6000. N/C at a distance of 1.5 m....

An electric field has an electric field strength 6000. N/C at a distance of 1.5 m. What is the strength of the field at a distance of 6.0 m? 24. An alpha (α) particle is positioned in an electric field such that the gravitational force acting on it is equal to the electrostatic force.              (qα = 3.2 x 10–19 C and mα = 6.64 x 10–27 kg) a) What is the direction of the electric field at this point?...

1. A point charge - and a conducting solid sphere of charge density +a(C/m?) and radius...

1. A point charge - and a conducting solid sphere of charge density +a(C/m?) and radius a are shown in Figure I (centers of both charges are al 2a distance from the origin o) a) Draw the electric field vectors at the origin 0. (4 pts) b) Determine the direction and magnitude of the NET electric field E, at origin O. (11 pts) +(C/m?) e) Calculate the NET electric potential V at the origin O(10 pts)

A uniform electric field of magnitude 260 V/m is directed in the positive x direction. A...

A uniform electric field of magnitude 260 V/m is directed in the positive x direction. A +12.0 µC charge moves from the origin to the point (x, y) = (20.0 cm, 50.0 cm). (a) What is the change in the potential energy of the charge field system? ______ J (b) Through what potential difference does the charge move? ______ V Full, detailed solutions please!

What is the force between a charge of 5 µC and 6 µC when they are...

What is the force between a charge of 5 µC and 6 µC when they are spaced 4.5 cm apart? Two equal but opposite charges, Q = 18e, are separated by a distance d = 5 mm. What is the electric field at the point P, which is a distance x = 22 µm from the positive charge? The two charges and point P are all along a single straight line. One electron is placed 4.4 cm from a stationary...