Around transmission lines there are generally electric and magnetic fields. If there ever were to be...

25. Around any electron in motion we have a. electric field. b. magnetic field. c. both...

25. Around any electron in motion we have a. electric field. b. magnetic field. c. both fields.    26. The lines of magnetic field generated by a current passing: a) are in the direction of the current b) are opposite to the direction of the current c) leave the cable radially OR are concentric circles around the cable 27. A field____can act on a moving electric charge. a. electric b. magnetic. c. both of them. 28. A magnetic field does...

Motion of Charge in Electric and Magnetic Fields  Consider the situation of two particles which...

Motion of Charge in Electric and Magnetic Fields  Consider the situation of two particles which have equal but opposite charges, +Q and -Q. The particles have identical mass. Discuss the following situations in terms of their motion and the work done on them by the relevant field. Where relevant, also provide a short discussion of the implications of these effects on the properties of the charged particles. If necessary, include diagrams to illuminate your solution. (a) For the positive...

You want to get an idea of the magnitude of magnetic fields produced by overhead power...

You want to get an idea of the magnitude of magnetic fields produced by overhead power lines. You estimate that a transmission wire is about 11m above the ground. The local power company tells you that the line operates at 13kV and provide a maximum of 57MW to the local area. A) Estimate the maximum magnetic field you might experience walking under such a power line, and compare to the Earth's field. [For an ac current, values are rms, and...

1. Why can electric fields not cross each other? A. Many electric field lines can exist...

1. Why can electric fields not cross each other? A. Many electric field lines can exist at any given point in space. B. No electric field lines can exist at any given point in space. C. Only a single electric field line can exist at any given point in space. D. Two electric field lines can exist at the same point in space. 2. By considering the molecules of an insulator, explain how an insulator can be overall neutral but...

How can you show that electric currents create magnetic fields? Check all that apply. If you...

How can you show that electric currents create magnetic fields? Check all that apply. If you place two wires with currents perpendicular to each other, they will be attracted each other. If you place a magnet near a closed circuit with current flowing, it will exert a force on the circuit wires. If you place a coil of wire near a magnet and direct a current through the coil, it will exert a force on the magnet, depending on its...

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?...

Select True or False for the following statements about electric field lines. E-field lines point outward...

Select True or False for the following statements about electric field lines. E-field lines point outward from positive charges. E-field lines point inward toward negative charges. E-field lines may cross. A positive point charge released from rest will initially accelerate along an E-field line. E-field lines make circles around positive charges. E-field lines do not begin or end in a charge-free region except at infinity. Where the E-field lines are dense the E-field must be weak.

Magnetic Force on a Moving Charge A velocity selector is a simple configuration of electric and...

Magnetic Force on a Moving Charge A velocity selector is a simple configuration of electric and magnetic fields that allows only those ions of a particular velocity in a narrow beam of ions to pass through it. A constant electric field E is oriented perpendicularly to a constant magnetic field B. The beam passes through the fields in the third direction, i.e., perpendicular to both E and B. A screen with a small hole blocks all the ions that are...

Faraday's law states that a changing magnetic field will create an electric field that curls around...

Faraday's law states that a changing magnetic field will create an electric field that curls around the magnetic field. To quantify this, we use the expression of flux (Φ) which is the magnetic field strength multiplied by the area (A) it’s passing through. This is given by: Φ = ?? The electric field is applied to the outside edge of this area. This created an electric potential that is referred to as an electro-motive force (EMF, ε). Faraday’s law can...

Do charges released from rest always move along electric field lines; i.e., does the charge stay...

Do charges released from rest always move along electric field lines; i.e., does the charge stay on the E field line at which it started? b) Based on your answer to a), would charges released with an initial velocity always move along electric field lines? c) Using kinematic quantities like position, velocity, and acceleration as well as the concept of a force to describe the general character of the motion of a [+] charge in motion near a single [+]...