- Magnetic Fields and Magnetic Forces
- Draw the magnetic Field Lines around the bar magnet shown below.
- Draw the magnetic field lines between the poles of the magnets shown below.
- Draw the magnetic field lines around a straight section of wire carrying a current horizontally left.
- Draw the magnetic field lines around a straight wire carrying current that is moving directly towards you.
- Determine the magnitude and direction of the force acting on a proton traveling 3.58 × 106 m/s horizontally west in a vertically upward magnetic field of strength 1.30 T.
- An electron with a speed of 1.80 × 106 m/s enters a 0.250 T magnetic field at an angle of 90°.
- What is the magnitude of the force?
- If the electron is moving north in a horizontal plane and the magnetic field is directed vertically downward, what direction will the electron be deflected?
- Indicate the direction a proton will be deflected in the situations below. B is the magnetic field and v represents the direction the proton is moving.
a) b) c) d) e) f)
- Electric current is flowing through a copper wire.
- What is the force per meter on the wire when carrying 9.8 A of current and is inserted perpendicularly to a 0.80 T magnetic field?
- What is the force if the angle between the wire and the magnetic field is 45°?
- A wire 1.5 m in length is carrying 6.5 A of current is oriented horizontally. At this point on the Earth’s surface, the dip angle of the Earth’s magnetic field makes an angle of 40° to the wire. What is the magnitude of the force on the wire due to the Earth’s magnetic field of 5.5 × 10-5 T at this point?
- How much current is flowing in a wire 4.2 m long if the maximum force on it is 0.900 N when places in a uniform 0.0800 T field?
- The force on a wire carrying 25.0 A is a maximum of 4.14 N when placed between the poles of a magnet. If the pole faces are 22 cm in diameter, what is the approximate strength of the magnetic field?
- Compare and contrast a meter and a motor.
- Electromagnets, Transformers, and Electromagnetic Induction
- Draw a step down transformer using the diagram of the core below.
- To induce current in a loop of wire, there must be a(n) ______magnetic field inside the loop.
- increasing
- decreasing
- changing
- Faraday determined that if the number of loops in a coil of wire increases, the ______induced in the wire by a changing magnetic field will ______.
- A transformer with a turns ratio of 13:1 (primary:secondary) is used in a wall socket (voltage 120 V) as part of a battery recharging unit.
- Is the transformer a step up or step down?
- What is the voltage supplied to the recharging unit?
- A step up transformer has a primary coil consisting of 200 turns and a secondary coil consisting of 3000 turns. The primary coil is supplied with an effective voltage of 90.0 V.
- What is the voltage in the secondary coil?
- If the current in the secondary coil is 2.0 A, what is the current in the primary coil?
- A step down transformer has 7500 turn in the primary coil and 125 turns in the secondary coil. The voltage across the primary coil is 7200 V. If the current in the secondary coil is 36 A, what is the current in the primary coil?
- The rectangular loop of wire shown in the diagram is pushed into the magnetic field which points inward as shown. In what direction is current induced?
- The north pole of a magnetic is inserted into a coil of wire as shown in the diagram. In which direction will current flow through the resistor R?
- See Instructor
- See Instructor
- See Instructor
- See Instructor
- 7.45 x 10-13 N
- a) 7.2 x 10-14 N
- a) right b) right
the page
e) zero f) up /
- a) 7.84 N
- 3.45 x 10-4 N
- See Instructor
- c. changing
- voltage/emf(current); increase
- a. step down
- a. 1350 V
- 0.6 A
- counterclockwise
- right to left