Date | November 2019 | Marks available | 1 | Reference code | 19N.1.HL.TZ0.33 |
Level | Higher level | Paper | Paper 1 | Time zone | 0 - no time zone |
Command term | Question number | 33 | Adapted from | N/A |
Question
X and Y are two plane coils parallel to each other that have a common axis. There is a constant direct current in Y.
X is first moved towards Y and later is moved away from Y. What, as X moves, is the direction of the current in X relative to that in Y?
Markscheme
C
Examiners report
Syllabus sections
- 22M.1.HL.TZ2.35: A conducting bar with vertices PQRS is moving vertically downwards with constant velocity v...
- 17N.2.HL.TZ0.2c: The cable between the satellites cuts the magnetic field lines of the Earth at right...
- 22M.2.HL.TZ1.8c.i: The switch is closed at time t = 0. Explain how the voltmeter reading varies after the switch...
-
22M.2.HL.TZ2.8a.ii:
State the fundamental SI unit for your answer to (a)(i).
- 17M.1.HL.TZ1.36: A conducting square coil is placed in a region where there is a uniform magnetic field. The...
-
22M.1.HL.TZ1.34:
The graph shows the variation of magnetic flux in a coil with time .
What represents the variation with time of the induced emf across the coil?
- 17N.2.HL.TZ0.2e: The magnetic field strength of the Earth is 31 μT at the orbital radius of the...
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17N.1.HL.TZ0.34:
The plane of a coil is positioned at right angles to a magnetic field of flux density B. The coil has N turns, each of area A. The coil is rotated through 180˚ in time t.
What is the magnitude of the induced emf?
A.
B.
C.
D.
- 17M.1.HL.TZ1.33: What are the units of magnetic flux and magnetic field strength?
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18N.1.HL.TZ0.33:
A ring of area S is in a uniform magnetic field X. Initially the magnetic field is perpendicular to the plane of the ring. The ring is rotated by 180° about the axis in time T.
What is the average induced emf in the ring?
A. 0
B.
C.
D. - 19N.1.HL.TZ0.34: A coil is rotated in a uniform magnetic field. An alternating emf is induced in the coil....
- 19M.1.HL.TZ2.29: A circular coil of wire moves through a region of uniform magnetic field directed out of the...
- 17M.2.HL.TZ1.8a: State Faraday’s law of induction.
- 17M.2.HL.TZ1.8b.i: Explain, using Faraday’s law of induction, how the transformer steps down the voltage.
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17M.1.HL.TZ2.34:
Three conducting loops, X, Y and Z, are moving with the same speed from a region of zero magnetic field to a region of uniform non-zero magnetic field.
Which loop(s) has/have the largest induced electromotive force (emf) at the instant when the loops enter the magnetic field?
A. Z only
B. Y only
C. Y and Z only
D. X and Y only
- 17M.1.HL.TZ2.33: The diagram shows a bar magnet near an aluminium ring. The ring is supported so that it is...
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21N.2.HL.TZ0.5b.ii:
Sketch, on the axes, a graph to show the variation with time of the magnitude of the emf induced in the loop.
-
19M.1.HL.TZ1.35:
The graph below shows the variation with time of the magnetic flux through a coil.
Which of the following gives three times for which the magnitude of the induced emf is a maximum?
A. 0, ,
B. 0, , T
C. 0, , T
D. , ,
- 18M.1.HL.TZ1.33: Two identical circular coils are placed one below the other so that their planes are both...
- 22M.2.HL.TZ2.8b.i: Explain why the graph becomes negative.
- 22M.2.HL.TZ2.8b.ii: Part of the graph is above the t-axis and part is below. Outline why the areas between the...
- 22M.2.HL.TZ2.8c: Predict the changes to the graph when the magnet is dropped from a lower height above the coil.
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20N.1.HL.TZ0.35:
A rectangular coil rotates at a constant angular velocity. At the instant shown, the plane of the coil is at right angles to the line . A uniform magnetic field acts in the direction .
What rotation of the coil about a specified axis will produce the graph of electromotive force (emf) against time ?
A. Through about
B. Through about
C. Through about
D. Through about
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20N.2.HL.TZ0.9a:
Explain, by reference to Faraday’s law of induction, how an electromotive force (emf) is induced in the coil.
- 21M.1.HL.TZ1.34: The conservation of which quantity explains Lenz’s law? A. Charge B. Energy C. Magnetic...
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21M.1.HL.TZ2.35:
A magnet connected to a spring oscillates above a solenoid with a 240 turn coil as shown.
The graph below shows the variation with time of the emf across the solenoid with the period, , of the system shown.
The spring is replaced with one that allows the magnet to oscillate with a higher frequency. Which graph shows the new variation with time of the current in the resistor for this new set-up?
- 21M.2.HL.TZ2.7b: A pendulum with a metal bob comes to rest after 200 swings. The same pendulum, released from...
- 18M.1.HL.TZ2.33: The current I flowing in loop A in a clockwise direction is increasing so as to induce a...
- 18M.1.HL.TZ2.34: A rectangular flat coil moves at constant speed through a uniform magnetic field. The...
- 21M.1.HL.TZ1.33: A conducting ring encloses an area of 2.0 cm2 and is perpendicular to a magnetic field...
- 19M.2.HL.TZ2.10a: While the magnet is moving towards the ring, state why the magnetic flux in the ring is...
- 19M.2.HL.TZ2.10b: While the magnet is moving towards the ring, sketch, using an arrow on Diagram 2, the...
- 19M.2.HL.TZ2.10c: While the magnet is moving towards the ring, deduce the direction of the magnetic force on...
- 21N.1.HL.TZ0.33: A small magnet is released from rest to drop through a stationary horizontal conducting...
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21N.2.HL.TZ0.5b.i:
Sketch, on the axes, a graph to show the variation with time of the magnetic flux linkage in the loop.
-
21N.2.HL.TZ0.5a:
Show that the speed of the loop is 20 cm s−1.
-
21N.2.HL.TZ0.5c.i:
There are 85 turns of wire in the loop. Calculate the maximum induced emf in the loop.
-
22M.2.HL.TZ1.8c.ii:
Determine the average emf induced across coil Y in the first 3.0 ms.
- 22M.2.HL.TZ2.8a.i: Write down the maximum magnitude of the rate of change of flux linked with the coil.