DP Physics Questionbank

Description

Nature of science:

Relationships: Examples of exponential growth and decay pervade the whole of science. It is a clear example of the way that scientists use mathematics to model reality. This topic can be used to create links between physics topics but also to uses in chemistry, biology, medicine and economics. (3.1)

Understandings:

• Capacitance
• Dielectric materials
• Capacitors in series and parallel
• Resistor-capacitor (RC) series circuits
• Time constant

Applications and skills:

• Describing the effect of different dielectric materials on capacitance
• Solving problems involving parallel-plate capacitors
• Investigating combinations of capacitors in series or parallel circuits
• Determining the energy stored in a charged capacitor
• Describing the nature of the exponential discharge of a capacitor
• Solving problems involving the discharge of a capacitor through a fixed resistor
• Solving problems involving the time constant of an RC circuit for charge, voltage and current

Guidance:

• Only single parallel-plate capacitors providing a uniform electric field, in series with a load, need to be considered (edge effect will be neglected)
• Problems involving the discharge of capacitors through fixed resistors need to be treated both graphically and algebraically
• Problems involving the charging of a capacitor will only be treated graphically
• Derivation of the charge, voltage and current equations as a function of time is not required

Data booklet reference:

International-mindedness:

• Lightning is a phenomenon that has fascinated physicists from Pliny through Newton to Franklin. The charged clouds form one plate of a capacitor with other clouds or Earth forming the second plate. The frequency of lightning strikes varies globally, being particularly prevalent in equatorial regions. The impact of lightning strikes is significant, with many humans and animals being killed annually and huge financial costs to industry from damage to buildings, communication and power transmission systems, etc

Utilization:

• The charge and discharge of capacitors obeys rules that have parallels in other branches of physics including radioactivity (see Physics sub-topic 7.1)

Aims:

• Aim 3: the treatment of exponential growth and decay by graphical and algebraic methods offers both the visual and rigorous approach so often characteristic of science and technology
• Aim 6: experiments could include (but are not limited to): investigating basic RC circuits; using a capacitor in a bridge circuit; examining other types of capacitors; verifying time constant

Directly related questions

• 18M.2.HL.TZ2.8d: State one assumption that needs to be made so that the Earth-thundercloud system may be modelled...
• 18M.2.HL.TZ2.8c.i: Show that about –11 C of charge is delivered to the Earth’s surface.
• 18M.2.HL.TZ2.8b.ii: Calculate in J, the energy stored in the system.
• 18M.2.HL.TZ2.8b.i: Calculate in V, the potential difference between the thundercloud and the Earth’s surface.
• 18M.2.HL.TZ2.8a: Show that the capacitance of this arrangement is C = 6.6 × 10–7 F.
• 18M.1.HL.TZ2.36: Three capacitors, each one with a capacitance C, are connected such that their...
• 18M.2.HL.TZ1.7c: The capacitor is fully charged and the space between the plates is then filled with a dielectric...
• 18M.2.HL.TZ1.7b: The capacitor is connected to a 16 V cell as shown.                                          ...
• 18M.2.HL.TZ1.7a: Calculate the distance between the plates.
• 18M.1.HL.TZ1.36: A parallel plate capacitor is connected to a cell of negligible internal resistance.            ...
• 17N.1.HL.TZ0.38: A capacitor of capacitance C discharges through a resistor of resistance R. The graph shows...
• 17N.1.HL.TZ0.37: Six identical capacitors, each of value C, are connected as shown. What is the total...
• 17M.2.HL.TZ2.3b: The resistance of the wire is 8.0 Ω. Determine the time taken for the capacitor to discharge...
• 17M.2.HL.TZ2.3a: The capacitance of the capacitor is 22 mF. Calculate the energy stored in the capacitor when it...
• 17M.1.HL.TZ2.36: A fully charged capacitor is connected to a resistor. When the switch is closed the capacitor...
• 17M.1.HL.TZ2.35: Two capacitors of different capacitance are connected in series to a source of emf of...
• 17M.1.HL.TZ1.35: A capacitor is charged by a constant current of 2.5 μA for 100 s. As a result the potential...
• 17M.1.HL.TZ1.34: A battery is used to charge a capacitor fully through a resistor of resistance R. The energy...
• 16M.2.HL.TZ0.7d: (i) The permittivity of the dielectric material in (c) is twice that of a vacuum. Calculate the...
• 16M.2.HL.TZ0.7c: A dielectric material is now inserted between the plates of the fully charged capacitor. State...
• 16M.2.HL.TZ0.7b: (i) The time constant of this circuit is 22s. State what is meant by the time constant. (ii)...
• 16M.2.HL.TZ0.7a: On the axes, draw a graph to show the variation with time of the voltage across the resistor.
• 16N.1.HL.TZ0.36: Three capacitors are arranged as shown. What is the total capacitance of the arrangement? A....
• 16N.1.HL.TZ0.35: A parallel-plate capacitor is connected to a battery. What happens when a sheet of dielectric...
• 16M.1.HL.TZ0.35: Which of the following...
• 16M.1.HL.TZ0.34: Three identical capacitors, each of...
• 16M.1.HL.TZ0.33: A parallel-plate capacitor is...
• 12N.1.HL.TZ0.39: The capacitance of a device is defined as the A. charge stored by the device.B. energy stored by...
• 13N.1.HL.TZ0.39: Capacitance of a capacitor is defined as the A. ability to store electrical charge.B. ratio of...
• 10M.1.HL.TZ1.34: The capacitance of a pixel of a CCD is 3.2 pF. A pulse of light is incident on the pixel and as a...