(A) using E = dV/dr, as potential is constant along equipotential surface, so dV = 0, so electric field is zero along equipotential surface.
(B)
A) if the voltage is constant along equipotential lines , would the electric field strength be...
How would I go about drawing the equipotential lines and
electric field lines? I'm not sure as to what this is supposed to
look like
3. In the following figure, the electric potential difference between the two parallel plates is 5.0 V. Draw four equipotential lines with 1-v difference between two neighboring lines and label each line with the corresponding voltage. Also draw four electric field lines in the
uestions for electric field experiment i) Info and draw on in it three more equipotential lines: one at the one slightly to the right of center and another slightly o 1. Use Fig. 5.6 center of the dipole, to the left of center sli Figure 5.6: The dashed lines are field lines for a dipole configuration. At each point it shows the direction that a positive probe-charge would follow if left alone there. The concentric lines around the poles are...
(c) How are the Electric Field lines related to the equipotential lines? How do they cross each other? What does Eq. 11.2 indicate? Use a sketch to illustrate the relation of the Electric Field lines to the equipotential lines. (d) The Electric Field gives the direction in which a positive test charge would move from a given point in space. Explain why different lines of force can never cross each other.
The equipotential lines in a region of electric field are shown in the diagram below. For each path indicated below, what is the work done by the electric field in moving a charge q = +9.2 x 10-7C along that path? Here V0 = +120 V. (a) from A to B(b) from A to C (c) from A to D(d) from D to C
What is the relationship between the density of the equipotential lines, the density of the electric field lines and the strength of the electric field? (10 points) 8.
(Figure 1) shows a region of space with an electric field.
Vertical lines indicate equipotential surfaces. A particle with
charge q = -4.8 nC is initially at the location of the -20-V
equipotential line. At time t = 0 the particle is released from
rest. Ignore the force exerted by Earth on the particle.
Part A: Estimate the magnitude of force exerted by the electric
field on the particle when it passes the 0-V equipotential
line.
Part B: Estimate the...
Two parallel plates
Equipotential Lines represent for us on a graph the same thing
Elevation Lines do for us on a map: They represent a line where the
Electric or Gravitational potential is a constant. Maps and voltage
graphs have even spacing between values (1V or 500ft or 100m etc)so
they can be read easier. These potentials were at 3V, 6V, 9V, 12V,
and 15V. In the figure are 5 lines of electric potential drawn from
positive charge at left...
Question 3 (#859685) Equipotential Lines) Which of the following statements is NOT true about equipotential lines? Select the correct answer O All points on an equipotential line are at the same voltage. A positively charged particle loses potential energy as it moves from one equipotential line to another equipotential line of a lower voltage. Your Answer Equipotential lines run perpendicular to the electric field lines on a 2- dimensional surface. For a charged particle on an equipotential line, there is...
How are equipotential lines used to obtain the electric field lines?
A) Identify the polarity of each terminalB) calculate the electric field for each segment of the electric field line given that the distance between the two digital multi-meter probe tips is 2.0*10^-2 m. C) Determine the potential difference between the two equipotential lines by summing the voltages along the electric field line. Compare this value to the potential difference found by subtracting the voltage of the two equipotential lines.