Prove that the equipotential surfaces are perpendicular to the electric field lines.

This is from an lab dealing with electric feild and equipotential lines. 1.If the electric potential...

This is from an lab dealing with electric feild and equipotential lines. 1.If the electric potential between two points is zero, what does that mean in terms of the electric field in terms of the test charge? 2. Is the electric field a vector a scalar field? Explain 3. Why must equipotential lines be perpendicular to electric field lines? 4. How much work is required to move a small test charge along an equipotential line? 5. Find the electric field...

Describe how you will plot the equipotential lines. Describe how would you draw the electric field...

Describe how you will plot the equipotential lines. Describe how would you draw the electric field map once you have the equipotential lines.

Did any of your field lines cross? Should they? Why, or why not? None of the...

Did any of your field lines cross? Should they? Why, or why not? None of the field lines crossed, nor should they. They are a line of constant potential and the equipotential can have only one value at a given point in space. If the electric field lines were to intersect, they would render a location with two different strong electric field vectors and so would not accurately represent equipotential lines. Did any of your equipotential surfaces cross? Should they?...

What angle do electric field lines make with the surface of a charge? At what angle...

What angle do electric field lines make with the surface of a charge? At what angle do electric field lines cross the equipotential lines? 3. As you follow the direction of the electric field, does electric potential increase or decrease? Is it the same for both positive and negative charges? 4.  Very near a charge or charge grouping, how are the equipotential lines oriented relative to the surface of the charge(s)?

Which statement regarding electric potential is NOT accurate? a. Electric potential is measured in units of...

Which statement regarding electric potential is NOT accurate? a. Electric potential is measured in units of volts. b. Electric potential depends on the position in an electric field. c. Electric potential depends on the amount of charge on a particle in an electric field. d. Electric potential depends on the strength of the electric field at a given position. Question 6 of 20 Which of the following statements regarding equipotentials and electric fields is accurate? a. Electric field lines are...

Equipotential Surface Plotting a) How much work is done by the electrostatic force on a point...

Equipotential Surface Plotting a) How much work is done by the electrostatic force on a point charge that is moved on an equipotential surface (line)? Explain. b) If the electric field lines are not normal to the equipotential surfaces, what would happen?

Do the equipotential lines get closer together or further apart at a sharp corner of a...

Do the equipotential lines get closer together or further apart at a sharp corner of a conductor? What about electric field lines? What does this indicate about the electric field strength in this region?

6-With a labelled sketch, illustrate the electric field and equipotential lines about a point charge. [2...

6-With a labelled sketch, illustrate the electric field and equipotential lines about a point charge. [2 marks] (b) A dipole, as illustrated in the following figure, consists of two charges of charge magnitude, q separated by a distance, d. Point P is separated from the dipole center by a distance, r along the x-axis. For this: i) sketch and label the electric field vector contributions at P due to the two point charges and the resultant net field vector at...

Is the magnitude of the electric field constant along an equipotential line? Is there an equation...

Is the magnitude of the electric field constant along an equipotential line? Is there an equation that can help to understand this relationship?

Prove that for a two-dimensional, incompressible, irrotational flow, stream-lines and equipotential lines form an orthogonal grid...

Prove that for a two-dimensional, incompressible, irrotational flow, stream-lines and equipotential lines form an orthogonal grid system, i.e.: (dy/dx|?=constant)*(dy/dx|?=constant)=-1