IV. Analysis ntrod A. Arrows indicate the directions of the electric field lines. Why are there...
E X P E RIM ENT 2 2 Fields and Equipotentials TV Laboratory Report Atlach graphs to Laboratory Report lal ib) ic) Figure 22.5 See Procedure Section B QUESTIONS 1. Directions of the fields are indicated on field lines. Why are no directions indicated on equipotential lines? greatest 2、 For the dipole configuration, in what region(s) does the electric field have the intensity? Explain how you know from your map, and justify. Don't forget units (ce EXPERIMEN T 2 2Fields...
Electric Fields and Potentials What do you think the electrie field lines look like in the region of space between a single positive charge and a single negative ch 6. arge? What do you think the equipotential lines look like in the region of space between a single positive charge and a single negative charge? 7. What is the shape of the electric field if there are two positive charges near each other? 8. 850 0 q What is the...
How to solve Part 4c? Sketches of electric field lines and equipotentials Sketch and answer 4 - A through 4 - D in your answer book. Consider different charge configurations as shown: 4 - A : Suppose you are a test charge and you start at some distance from the charge q = +1 below, such as at the point X. Starting at point X, what path could you move along without doing any work? i.e. which Ē. ds is...
3.1 Pre-lab In the lab on electric potential and electric field lines, you noted that charged par- ticles produce electric fields and these electric fields, in turn, act on charged par- ticles. However, you then proceeded to produce an electric field geometry using conductors held at a particular electric potential. What happened to the electric charges? Electric charge and electric potential are closely related to each other. Putting charge on a conductor raises its electric potential. It is usually much...
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...
Question 9 of 17> Select the options that best complete the statement. follow electric field lines, because never Positively charged particle trajectories never can but do not have to always electric field lines are de ist charges travel. about us careers privacy poliky erms ofuse contactus hetp ion 9 of 17> Select the options that best complete the statement. Positively charged particle trajectories never follow electric field lines, because electric field lines are defined by the path positive test charges...
Please answer WARM-UP and PREDICTION. PROBLEM #1: ELECTRIC FIELD VECTORS As part of your internship with a local power company, you have been assigned to a team reviewing published research about the effects of electric fields on human health. To evaluate the merits of apparently conflicting research, you need a computer program to simulate the electric field due to complicated charge configurations. Your team leader has assigned you the task of evaluating such a program. To test the program, you...
Page #4 Physics Il caline lab: Electric Field & Elecric Potential Part I: Electric Field Open the PHET simulation "Charges and Fields". Add positive and negative charges as shown in the diagram below. Draw appropriate electric field lines around and in between the two charges. Use the tools available in the software and then draw manually. Where is the electric field the largest? (label the point #1 in your diagram) 2. Where is the electric field equal to zero? (label...
please answer all and explain Review Exam 1 PH 202 Draw electric field lines for the charge configurations shown below. Draw electric field vectors and equipotential surfaces. a. Positive point charge, b. Negative point-charge, c. Electric dipole, and d. Two negative point charges separated by a distance d point chareye 2. State Coulomb's Law. Des cribes the foru point 3. If you bring a negatively charged insulator near two uncharged metallic spheres that are in contact and then separate the...
Consider a uniform electric field in the gap between two oppositely charged plates. A singly charged negative ion of mass, m, enters the field with an initial velocity, v(), straight to the right, as shown in the diagram below. The trajectory of the negative ion is such that it enters from the left side of the gap, near the negative plate, and just barely missing hitting the positive plate as it exits the device, as indicated by the dashed line...