Questions 1. If the potential is the same everywhere on the conducting electrodes, what is the...
1. Describe a uniform electric field. 2. Explain a practical method to create a uniform electric field. 3. In the electrode configuration of Figure 3-a, notice that the equipotential lines are circles which are closer to each other near the point terminal. Explain. (Hint: refer to the relation of the electric field around a point charge, and the relation where DV is the difference in potential between any two points, and r is the distance between them.) 4. In principle,...
What is the electric potential inside a conductor: Zero everywhere The same everywhere Varies, depending on the shape of the conductor Varies, depending on the amount of charge on the conductor Are electric field lines more or less dense near a collection of charge? Explain.
Lab 6 - Electric Field Mapping PRELAB QUESTIONS 1. What is the difference between electric potential energy, electric field, and electric potential? 2. What are equipotential surfaces and how are they related to the electric field? 3. Two flat, parallel electrodes 2.5 cm apart are kept at potentials of 20 V and 35 V. Estimate the electric field strength and direction between them.
gree with cular to HOMEWORK FOR LAB 3 ELECTRICAL AND GRAVITATIONAL POTENTIAL 1. In each of the drawings below, E-4.0 N/C and d 1.5 m. For each diagram a The work done by the electric field in moving a +50 x 10 C charge c field. calculate from A to B b. The difference e. The potential difference between A and B between the charge's potential energy at B and at A. 2. What is the relationship between equipotential surfaces...
Part 1 Part 2. Consider the equipotential surfaces in the picture. The equipotential lines are separated by 1 cm 300 V -+ +- -200 V -100 V What is the magnitude of the average electric field between points A and C? The maximum charge that can be stored on a conducting sphere is determined by the electric field required the ionize the material surrounding it. Consider a uniform conducting sphere in air. Air ionizes when the electric field at the...
Physics Lab #7-Electric Potential and Field NAME: Pre-lab questions: 1) S ketch the expected electric field patterns for equal and opposite charges separated by a distance d. Repeat for 2 infinite lines of equal and opposite charge separated by a d. How would you expect the electric field pattern to change of the lines have a finite length? (Hint: The line-line electrode arrangement should produce an electric field that is similar to a charged capacitor with a large plate separation.)...
1) Do the electric field lines cross? Can two equipotential 2) Explain why the equipotential surfaces should be always 3) A uniform electric field is parallel to the y-axis. What lines ever cross? Explain. perpendicular to the electric field lines? direction can a charge be displaced in this field without any external work being done on the charge?
What is the potential difference between the electrodes while the capacitor is attached to the battery? Express your answer with the appropriate units. ReviewI Constants | Periodic Table Two 12.0-cm-diameter electrodes 0.50 cm apart form a parallel-plate capacitor. The electrodes are attached by metal wires to the terminals of a 13 V battery. AVI-Value Units Submit Request Answer Part D What is the charge on each electrode after insulating handles are used to pull the electrodes away from each other...
Advance Seudy Assignment: Fields & Equipotentials Name QUESTIONS 1. Explain the term electric field. What is its definition? Explain with an example what the Sec size and direction of an electric field at a given point means. 2. What is meant by electric potential? What is an equipotential surface? Explain the relationship between equipotential lines and electric field lines. Why is this so? 3. Explain how you will map the electric field of a dipole in this exercise. 4. Using...
A parallel-plate capacitor has 4.6 cm × 4.6 cm electrodes with surface charge densities ±1.0×10−6C/m2. A proton traveling parallel to the electrodes at 2.0×106 m/s enters the center of the gap between them. By what distance has the proton been deflected sideways when it reaches the far edge of the capacitor? Assume the field is uniform inside the capacitor and zero outside the capacitor