Date | November 2016 | Marks available | 2 | Reference code | 16N.2.HL.TZ0.9 |
Level | Higher level | Paper | Paper 2 | Time zone | Time zone 0 |
Command term | Determine | Question number | 9 | Adapted from | N/A |
Question
A beam of electrons e– enters a uniform electric field between parallel conducting plates RS. RS are connected to a direct current (dc) power supply. A uniform magnetic field B is directed into the plane of the page and is perpendicular to the direction of motion of the electrons.
The magnetic field is adjusted until the electron beam is undeflected as shown.
Identify, on the diagram, the direction of the electric field between the plates.
The following data are available.
Separation of the plates RS | = 4.0 cm |
Potential difference between the plates | = 2.2 kV |
Velocity of the electrons | = 5.0×105 m s–1 |
Determine the strength of the magnetic field B.
The velocity of the electrons is now increased. Explain the effect that this will have on the path of the electron beam.
Markscheme
direction indicated downwards, perpendicular to plates
Arrows must be between plates but allow edge effects if shown. Only one arrow is required.
\(E = \frac{V}{d} = 55\,000\) «Vm–1»
B = «\(\frac{{55\,000}}{{5 \times {{10}^5}}} = \)» 0.11 «T»
ECF applies from MP1 to MP2 due to math error.
Award [2] for a bald correct answer.
ALTERNATIVE 1
magnetic force increases
OR
magnetic force becomes greater than electric force
electron beam deflects “downwards” / towards S
OR
path of beam is downwards
ALTERNATIVE 2
when v increases, the B required to maintain horizontal path decreases
«but B is constant» so path of beam is downwards
Do not apply an ecf from (a).
Award [1 max] if answer states that magnetic force decreases and therefore path is upwards.
Ignore any statement about shape of path
Do not allow “path deviates in direction of magnetic force” without qualification.
Examiners report
Syllabus sections
- 17N.3.SL.TZ0.2b: State the value of the intercept on the R axis.
- 17N.3.SL.TZ0.2a: Show that the gradient of the graph is equal to \(\frac{1}{e}\).
- 17N.2.SL.TZ0.3c: Draw a circuit diagram to show how you could measure the resistance of the carbon-film...
- 17N.2.SL.TZ0.3b: The current direction is now changed so that charge flows vertically through the...
- 17N.2.SL.TZ0.3a.iii: State why knowledge of quantities such as resistivity is useful to scientists.
- 17N.2.SL.TZ0.3a.ii: The film must dissipate a power less than 1500 W from each square metre of its surface to...
- 17N.2.SL.TZ0.3a.i: The resistance of the carbon film is 82 Ω. The resistivity of carbon is 4.1 x 10–5 Ω m....
- 17N.2.HL.TZ0.8c: The electron is replaced by a proton which is also released from rest at X. Compare, without...
- 17N.2.HL.TZ0.8b: An electron is placed at X and released from rest. Draw, on the diagram, the direction of the...
- 17N.2.HL.TZ0.8a: Outline what is meant by electric field strength.
- 17N.2.HL.TZ0.2d: Satellite X must release ions into the space between the satellites. Explain why the current...
- 17N.2.HL.TZ0.2c: The cable between the satellites cuts the magnetic field lines of the Earth at right...
- 17N.1.SL.TZ0.20: The diagram shows two current-carrying wires, P and Q, that both lie in the plane of the...
- 17N.1.SL.TZ0.19: With reference to internal energy conversion and ability to be recharged, what are...
- 17N.1.SL.TZ0.18: Kirchhoff’s laws are applied to the circuit shown. What is the equation for the dotted...
- 17N.1.SL.TZ0.17: In the circuit shown, the fixed resistor has a value of 3 Ω and the variable resistor can be...
- 17N.1.HL.TZ0.18: The diagram shows the magnetic field surrounding two current-carrying metal wires P and...
- 17N.1.HL.TZ0.15: Two wires, X and Y, are made from the same metal. The wires are connected in series. The...
- 17M.3.SL.TZ2.2b: In one experiment a student obtains the following graph showing the variation with current I...
- 17M.3.SL.TZ2.2a: An ammeter and a voltmeter are connected in the circuit. Label the ammeter with the letter A...
- 17M.2.HL.TZ2.6d: The two cables in part (c) are suspended a constant distance apart. Explain how the magnetic...
- 17M.2.HL.TZ2.6b.iii: Determine the power dissipated in the cable per unit length.
- 17M.2.HL.TZ2.6b.ii: Calculate the peak current in the cable.
- 17M.2.HL.TZ2.6b.i: Calculate the radius of each wire.
- 17M.2.HL.TZ1.4a.iii: Calculate the power dissipated in the cable.
- 17M.2.SL.TZ2.5b.ii: There is a current of 730 A in the cable. Show that the power loss in 1 m of the cable is...
- 17M.2.SL.TZ2.5a: The copper wires and insulator are both exposed to an electric field. Discuss, with reference...
- 17M.2.SL.TZ1.5b.i: Explain which interaction is responsible for this decay.
- 17M.2.SL.TZ1.4c: The heater changes the temperature of the water by 35 K. The specific heat capacity of water...
- 17M.2.SL.TZ1.4b: Explain, in terms of electrons, what happens to the resistance of the cable as the...
- 17M.2.SL.TZ1.4a.ii: Calculate the resistance of the cable.
- 17M.2.SL.TZ1.4a.i: Calculate the current in the copper cable.
- 17M.1.HL.TZ2.17: The diagram shows the path of a particle in a region of uniform magnetic field. The field is...
- 17M.1.HL.TZ2.15: Positive charge is uniformly distributed on a semi-circular plastic rod. What is the...
- 17M.1.HL.TZ1.17: Electrons, each with a charge e, move with speed v along a metal wire. The electric current...
- 17M.1.SL.TZ2.21: A positively-charged particle moves parallel to a wire that carries a current...
- 17M.1.SL.TZ2.20: A circuit contains a cell of electromotive force (emf) 9.0 V and internal resistance 1.0 Ω...
- 17M.1.SL.TZ2.19: A wire has variable cross-sectional area. The cross-sectional area at Y is double that at...
- 17M.1.SL.TZ2.18: The diagram shows two equal and opposite charges that are fixed in place. At which points...
- 17M.1.SL.TZ1.21: An electron travelling at speed v perpendicular to a magnetic field of strength B experiences...
- 17M.1.SL.TZ1.20: A cell is connected in series with a resistor and supplies a current of 4.0 A for a time of...
- 17M.1.SL.TZ1.19: An electron is accelerated through a potential difference of 2.5 MV. What is the change in...
- 17M.1.SL.TZ1.18: The graph shows the variation of current with potential difference for a filament...
- 17M.1.SL.TZ1.15: Two pulses are travelling towards each other. What is a possible pulse shape when the...
- 09N.1.SL.TZ0.21: A positively charged particle enters the space between two charged conducting plates, with a...
- 09N.1.SL.TZ0.20: Which of the following diagrams illustrates the electric field pattern of a negatively...
- 09N.1.SL.TZ0.18: In the circuits below the cells have the same emf and zero internal resistance. The resistors...
- 09N.1.SL.TZ0.17: A cylindrical conductor of length \(l\), diameter \(D\) and resistivity \(\rho \) has...
- 09N.1.SL.TZ0.16: A cell of \({\text{emf }}\varepsilon \) and internal resistance \(r\) delivers current to a...
- 09N.1.HL.TZ0.9: Four point charges of magnitudes \( + q\), \( + q\), \( - q\), and \( - q\) are held in place...
- 16N.2.SL.TZ0.7b: Components R and T are placed in a circuit. Both meters are ideal. Slider Z of the...
- 16N.2.SL.TZ0.7a: (i) State how the resistance of T varies with the current going through T. (ii) Deduce,...
- 16M.2.HL.TZ0.6a: Two cells of negligible internal resistance are connected in a circuit. The top cell has...
- 16N.2.HL.TZ0.9c: The velocity of the electrons is now increased. Explain the effect that this will have on the...
- 16N.2.HL.TZ0.9a: Identify, on the diagram, the direction of the electric field between the plates.
- 16M.2.SL.TZ0.5d: The diagram shows a cross-sectional view of the connecting wire in (c). The wire which...
- 16M.2.SL.TZ0.5c: A connecting wire in the circuit has a radius of 1.2mm and the current in it is 3.5A. The...
- 16M.2.SL.TZ0.5b: The student adjusts the variable resistor and takes readings from the ammeter and voltmeter....
- 16M.2.SL.TZ0.5a: State what is meant by an ideal voltmeter.
- 16M.2.SL.TZ0.1e: The electric motor is connected to a source of potential difference 120V and draws a current...
- 16N.1.HL.TZ0.17: A 12V battery has an internal resistance of 2.0Ω. A load of variable resistance is connected...
- 16N.1.SL.TZ0.21: A wire carrying a current \(I\) is at right angles to a uniform magnetic field of strength B....
- 16N.1.SL.TZ0.20: A cell of emf 4V and negligible internal resistance is connected to three resistors as shown....
- 16N.1.SL.TZ0.19: An electrical circuit is shown with loop X and junction Y. What is the correct expression...
- 16N.1.SL.TZ0.18: A –5µC charge and a +10µC charge are a fixed distance apart. Where can the electric field...
- 16M.1.HL.TZ0.12: A circuit consists of a cell of electromotive force (emf) 6.0V and negligible...
- 16M.1.SL.TZ0.21: ...
- 16M.1.SL.TZ0.20: A circuit consists of a cell of electromotive force (emf) 6.0V and negligible internal...
- 16M.1.SL.TZ0.19: The graph shows the variation of current I in a device with potential difference V across...
- 16M.1.SL.TZ0.18: Thr...
- 10N.2.SL.TZ0.B2Part1.c: (i) Determine the magnitude of the electric field between the base of the thundercloud...
- 10N.2.SL.TZ0.B2Part1.b: A thundercloud can be modelled as a negatively charged plate that is parallel to the...
- 10N.2.SL.TZ0.A3b: The graph shows the current-voltage characteristics for the component X. Component X is...
- 10N.2.SL.TZ0.A3a: Draw the complete diagram of the circuit that uses a potential divider, ammeter, voltmeter...
- 10N.1.SL.TZ0.22: An electron enters the vacuum between two oppositely charged plates with velocity \(v\). The...
- 10N.1.SL.TZ0.19: A current is established in a coil of wire in the direction shown. The direction of the...
- 10N.1.SL.TZ0.18: Three identical resistors are connected to a battery as shown. Which of the following is a...
- 10N.1.SL.TZ0.17: The circuit shows a resistor R connected in series with a battery and a resistor of...
- 10N.1.SL.TZ0.16: Two resistors, made of the same material, are connected in series to a battery. The length of...
- 10M.1.SL.TZ1.21: An electron travelling in the direction shown by the arrow X, enters a region of uniform...
- 10M.1.SL.TZ1.20: Three positive point charges of equal magnitude are held at the corners X, Y and Z of a...
- 10M.1.SL.TZ1.18: The electromotive force (emf) of a cell is defined as A. the power supplied by the cell...
- 10M.1.SL.TZ1.17: A resistor of resistance \({\text{12 }}\Omega \) is connected in series with a cell of...
- 09M.1.SL.TZ1.20: Which diagram best represents the electric field due to a negatively charged conducting...
- 09M.1.SL.TZ1.17: Two \(6{\text{ }}\Omega \) resistors are connected in series with a 6 V cell. A student...
- 09M.1.SL.TZ1.16: Two rectangular blocks, \(X\) and \(Y\), of the same material have different dimensions but...
- 09M.1.HL.TZ1.23: A current carrying wire is in the same plane as a uniform magnetic field. The angle between...
- 14M.2.SL.TZ2.6d: (i) Draw a circuit diagram of the experimental arrangement that will enable the student...
- 14M.2.SL.TZ2.5g: (i) The diagram shows a length of copper wire that is horizontal in the magnetic field of...
- 14M.2.SL.TZ2.5f: The diagram shows a current I in a vertical wire that passes through a hole in a horizontal...
- 14M.2.SL.TZ2.5e: Distinguish between an insulator and a conductor.
- 14M.2.HL.TZ2.8a: (i) Distinguish between an insulator and a conductor. (ii) Outline what is meant by...
- 14N.2.SL.TZ0.6h.ii: Discuss the subsequent motion of the electron.
- 14N.2.SL.TZ0.6h.i: Calculate the initial acceleration of the electron.
- 14N.2.SL.TZ0.6g.ii: On the axes, draw a graph to show the variation of the electric field strength \(E\) with...
- 14N.2.SL.TZ0.6g.i: Show that the magnitude of the electric field strength at the surface of the sphere is about...
- 14N.2.SL.TZ0.2b.iv: Calculate the energy dissipated per second in the variable resistor.
- 14N.2.SL.TZ0.2b.iii: Determine the internal resistance of the cell.
- 14N.2.SL.TZ0.2b.ii: Show that the emf of the cell is 1.25 V.
- 14N.2.SL.TZ0.2b.i: Draw on the diagram the positions of the ammeter and voltmeter.
- 14N.2.SL.TZ0.2a: Define electromotive force (emf ).
- 14N.2.HL.TZ0.8d.ii: Using the graph, determine the current in the circuit.
- 14N.2.HL.TZ0.8d.i: On the graph, sketch the variation of \(V\) with \(I\) for the cell.
- 14N.2.HL.TZ0.8b: Outline, with reference to charge carriers, what is meant by the internal resistance of a cell.
- 15N.2.SL.TZ0.6g: Calculate the electromotive force (emf) of the cell.
- 15N.2.SL.TZ0.6f.ii: Determine the internal resistance of the cell.
- 15N.2.SL.TZ0.6f.i: Outline what is meant by the internal resistance of a cell.
- 15N.2.SL.TZ0.6e: Show that the current in the circuit is approximately 0.70 A when \(R = 0.80{\text{ }}\Omega \).
- 15N.2.SL.TZ0.6d: An ammeter and a voltmeter are used to investigate the characteristics of a variable resistor...
- 15N.1.SL.TZ0.19: A cylindrical resistor of length \(l\) is made from a metal of mass \(m\). It has a...
- 15N.2.HL.TZ0.9h: The upper section of wire is adjusted to make an angle of 30° with the lower section of wire....
- 15N.2.HL.TZ0.9g.ii: Each cubic metre of the wire contains approximately \(8.5 \times {10^{28}}\) free electrons....
- 15N.2.HL.TZ0.9g.i: Calculate the magnetic force acting per unit length on the upper section of wire.
- 15N.2.HL.TZ0.9f: Deduce what happens to the reading on the electronic balance when the current is switched on.
- 15N.2.HL.TZ0.9d: The cell may be damaged if it dissipates a power greater than 1.2 W. Outline why damage in...
- 15N.2.HL.TZ0.8f.iii: Determine the input voltage to the transformer if the power loss in the cables from the power...
- 15N.2.HL.TZ0.8f.ii: Calculate the power supplied to the transformer.
- 15N.2.HL.TZ0.8f.i: Calculate the current in the cables connected to the town
- 15N.1.HL.TZ0.18: A filament lamp and a semiconducting diode have the voltage–current (\(V\)–\(I\))...
- 15M.1.HL.TZ1.19: A circuit is formed by connecting a resistor between the terminals of a battery of...
- 15M.1.HL.TZ1.32: An ion follows a circular path in a uniform magnetic field. Which single change decreases the...
- 15M.1.SL.TZ2.18: The diagram shows a circuit used to investigate internal resistance of a cell. The...
- 15M.1.SL.TZ1.18: Four resistors are connected as shown. What is the total resistance between X and Y? A. 3...
- 15M.1.SL.TZ2.16: What is the definition of electric current? A. The ratio of potential difference across a...
- 15M.1.SL.TZ2.21: A long, straight, current-carrying wire is placed between a pair of magnets as shown. What is...
- 15M.1.HL.TZ2.17: The diagram shows an electric circuit containing a potentiometer of maximum resistance R. The...
- 15M.2.SL.TZ1.5a: (i) Define electromotive force (emf). (ii) State how the emf of the battery can be measured.
- 15M.2.HL.TZ1.3a: Define electromotive force (emf).
- 15M.2.HL.TZ1.3b: The graph below shows the variation with temperature T of the resistance RX of the...
- 15M.2.HL.TZ1.8a: Identify, on the diagram, the direction of the force on the coil with the current directions...
- 15M.2.HL.TZ1.8b: Calculate the maximum magnetic force acting on the coil.
- 15M.2.SL.TZ2.5e: The 24 Ω resistor is covered in an insulating material. Explain the reasons for the...
- 15M.2.SL.TZ2.5f: An electric circuit consists of a supply connected to a 24Ω resistor in parallel with a...
- 15M.2.SL.TZ2.6e: Six point charges of equal magnitude Q are held at the corners of a hexagon with the signs of...
- 15M.2.HL.TZ2.9a: A 24Ω resistor is made from a conducting wire. (i) The diameter of the wire is 0.30 mm and...
- 15M.2.HL.TZ2.9b: An electric circuit consists of a supply connected to a 24Ω resistor in parallel with a...
- 14M.1.SL.TZ1.16: Each of the resistors in the arrangements below has resistance R. Each arrangement is...
- 14M.1.SL.TZ1.17: Two resistors of resistance 10 Ω and 20 Ω are connected in parallel to a cell of negligible...
- 14M.1.SL.TZ1.18: A battery of emf 12 V and negligible internal resistance is connected to a resistor of...
- 14M.1.SL.TZ1.20: Three parallel wires, X, Y and Z, carry equal currents. The currents in X and Z are directed...
- 14M.1.SL.TZ1.21: Point P is at the same distance from two charges of equal magnitude and opposite sign. What...
- 14M.1.SL.TZ2.17: Which of the following is a statement of Ohm’s law? A. The resistance of a conductor is...
- 14M.1.SL.TZ2.18: Three identical filament lamps W, X and Y are connected in the circuit as shown. The cell has...
- 14M.1.SL.TZ2.19: An electron is travelling in a region of uniform magnetic field. At the instant shown, the...
- 14M.2.SL.TZ1.3a: Calculate the magnitude of the electric force acting on the proton when it is in the electric...
- 14M.2.SL.TZ1.3b: A uniform magnetic field is applied in the same region as the electric field. A second proton...
- 15N.1.SL.TZ0.23: An electron is moving parallel to a straight current-carrying wire. The direction of...
- 15N.1.SL.TZ0.22: A \( + 3{\text{ C}}\) charge and a \( - 4{\text{ C}}\) charge are a distance \(x\) apart. P...
- 15N.1.SL.TZ0.20: Three resistors of resistance \(R\) are connected in parallel across a cell of electromotive...
- 14N.1.SL.TZ0.16: A cylindrical resistor of volume V and length l has resistance R. The resistor has a uniform...
- 14N.1.SL.TZ0.18: A lamp is connected to an electric cell and it lights at its working voltage. The lamp is...
- 14N.1.HL.TZ0.19: A voltmeter of resistance 50kΩ is used to measure the electric potential difference in a...
- 14N.1.HL.TZ0.18: A lamp is connected to an electric cell and it lights at its working voltage. The lamp is...
- 11N.1.SL.TZO.16: A cell is connected in series with a 2.0Ω resistor and a switch. The voltmeter is connected...
- 11N.1.SL.TZO.19: Which of the following is the SI unit of gravitational field strength? A. NB. N mC. Nkg–1D....
- 11N.1.SL.TZO.20: Which of the following is the best representation of the electric field lines around a...
- 11N.1.SL.TZO.21: The diagram shows two long wires X and Y carrying identical currents in the same...
- 12N.1.SL.TZ0.20: A cell with an emf of 2.0 V and negligible internal resistance is connected across a 1.00 m...
- 11N.1.HL.TZ0.21: A resistor has a resistance R. The potential difference across the resistor is V. Which of...
- 12N.1.SL.TZ0.19: An ideal ammeter is used to measure the current in a resistor. Which of the following gives...
- 12N.1.SL.TZ0.21: An electron has a kinetic energy of 4.8×10–10J. What is the equivalent value of this kinetic...
- 12N.1.SL.TZ0.24: The magnetic field produced by a current in a straight wire is in A. the same direction as...
- 12N.1.HL.TZ0.20: An ideal ammeter is used to measure the current in a resistor. Which of the following gives...
- 13N.1.HL.TZ0.25: A metal rod M is falling vertically within a horizontal magnetic field. The metal rod and...
- 13N.1.SL.TZ0.17: A resistor X of resistance R is made of wire of length L and cross-sectional area A. Resistor...
- 13N.1.SL.TZ0.20: Which diagram represents the pattern of electric field lines of two small positive point...
- 13N.1.SL.TZ0.19: Each of the resistors in the circuit has a resistance of 2.0 Ω. The cell has an emf of 3.0 V...
- 13M.2.SL.TZ1.7b: The diagram shows a pair of horizontal metal plates. Electrons can be deflected...
- 13M.2.SL.TZ1.7c: The diagram shows two isolated electrons, X and Y, initially at rest in a vacuum. The initial...
- 13M.2.SL.TZ1.7a: Define electric field strength.
- 12M.1.SL.TZ2.16: A metal wire X with length L and radius r has a resistance R. A wire Y of length 4L made from...
- 13M.2.SL.TZ1.8d: The diagram shows 12 photovoltaic cells connected in series and in parallel to form a module...
- 12M.1.SL.TZ1.16: The ampere is defined in terms of A. power dissipated in a wire of known length,...
- 12M.1.SL.TZ2.17: Three identical filament lamps, X, Y and Z, are connected as shown to a battery of...
- 12M.1.SL.TZ2.18: Which of the following is the correct way of connecting an ammeter and of connecting a...
- 12M.1.SL.TZ1.21: Three parallel wires, X, Y and Z, carry equal currents into the page. Which arrow...
- 12M.1.SL.TZ2.20: Coulomb’s law refers to electric charges that are A. on any charged objects.B. charged...
- 12M.1.SL.TZ2.21: Which of the following will not give rise to a magnetic field? A. A moving electronB. A...
- 12M.1.SL.TZ1.17: A battery of emf 6.0V is connected to a 2.0Ω resistor. The current in the circuit is 2.0A....
- 12M.1.SL.TZ1.18: Which of the following gives the resistances of an ideal ammeter and an ideal voltmeter?
- 12M.1.HL.TZ1.19: A proton p is at rest between the poles of two horizontal magnets as shown below. The...
- 11M.1.SL.TZ2.16: Two electrodes, separated by a distance d, in a vacuum are maintained at a constant potential...
- 11M.1.SL.TZ2.17: The graph shows the I–V characteristics of two resistors. When resistors X and Y...
- 11M.1.SL.TZ2.20: Two isolated point charges, -7 μC and +2 μC, are at a fixed distance apart. At which...
- 13M.2.SL.TZ2.6b: In a simple model of the hydrogen atom, the electron can be regarded as being in a circular...
- 13M.2.SL.TZ2.6c: An electric cell is a device that is used to transfer energy to electrons in a circuit. A...
- 11M.1.HL.TZ2.6: The diagram below shows a uniform electric...
- 13M.2.SL.TZ2.6a: State Coulomb’s law.
- 11M.1.SL.TZ2.21: A long straight wire carries an electric current perpendicularly out of the...
- 11M.1.SL.TZ2.22: Which nucleons in a nucleus are involved in the Coulomb interaction and the...
- 11M.1.HL.TZ2.22: A long straight wire...
- 11M.1.HL.TZ2.20: Two resistors, of resistance R1 and...
- 11M.1.HL.TZ2.21: Two isolated point charges,...
- 13M.1.SL.TZ2.21: Three wires, P, Q and R, carry equal currents directed into the plane of the paper. Which...
- 13M.1.SL.TZ2.16: A copper wire with length L and radius r has a resistance R. What is the radius of a copper...
- 13M.1.SL.TZ2.17: An electric circuit consists of three identical resistors of resistance R connected to a cell...
- 13M.1.SL.TZ2.18: A proton is accelerated from rest through a potential difference of 1000 V. What is the...
- 13M.1.HL.TZ2.20: A copper wire with length L and radius r has a resistance R. What is the radius of a copper...
- 13M.1.HL.TZ2.25: The electric potential is VR at a point R in an electric field and at another point S the...
- 12M.2.SL.TZ2.7b: The plates in (a) are replaced by a cell that has an emf of 12.0 V and internal...
- 12M.2.SL.TZ2.7a: Ionized hydrogen atoms are accelerated from rest in the vacuum between two vertical parallel...
- 11M.2.SL.TZ2.9a: ...
- 11M.2.SL.TZ2.9b: ...
- 12M.2.SL.TZ2.9a: The magnitude of gravitational field strength g is defined from the equation shown...
- 12M.2.SL.TZ1.9b: (i) Calculate the resistance of the filament lamp when the potential difference across it is...
- 12M.2.SL.TZ1.9c: Two identical filament lamps are connected in series with a cell of emf 6.0 V and negligible...
- 12M.2.HL.TZ2.7a: The magnitude of gravitational field strength g is defined from the equation shown...
- 12M.2.HL.TZ2.7b: In a simple model of the hydrogen atom, the electron is regarded as being in a circular orbit...
- 11N.2.SL.TZ0.2b: A tungsten filament lamp is marked 6.0 V, 15 W. (i) Show that the resistance of the lamp at...
- 11N.2.HL.TZ0.10d: (d) The diagram shows part of a potential divider circuit used to measure the...
- 11N.2.SL.TZ0.2c: The diagram shows part of a potential divider circuit used to measure the current-potential...
- 11N.2.SL.TZ0.2a: Tungsten is a conductor used as the filament of an electric lamp. The filament of the lamp is...
- 11N.2.SL.TZ0.9b: The electric motor can be adjusted such that, after an initial acceleration, the load moves...
- 11N.2.HL.TZ0.10a: (i) On the diagram above, draw an arrow to show the direction of the electric field at point...
- 11N.2.HL.TZ0.10e: A student sets up a different circuit to measure the I–V graph. The cell has an emf of 6.0 V...
- 12N.2.SL.TZ0.2a: State how a magnetic field arises.
- 12N.2.SL.TZ0.8a: State Ohm’s law.
- 12N.2.SL.TZ0.2b: On the diagram below, sketch the magnetic field pattern around the long straight...
- 12N.2.SL.TZ0.8b: A lighting system is designed so that additional lamps can be added in parallel. The...
- 13N.2.SL.TZ0.5d: Outline, with reference to the graph and to Ohm’s law, whether or not each component is ohmic.
- 13N.2.SL.TZ0.5e: Components X and Y are connected in parallel. The parallel combination is then connected in...
- 13N.2.SL.TZ0.4a: Define electric field strength.
- 13N.2.SL.TZ0.4b: A simple model of the proton is that of a sphere of radius 1.0×10–15m with charge...
- 13N.2.SL.TZ0.4c: Protons travelling with a speed of 3.9×106ms–1 enter the region between two charged parallel...
- 11M.1.SL.TZ1.17: One electronvolt is equal to A. 1.6×10−19 C.B. 1.6×10−19 J.C. 1.6×10−19 V.D. 1.6×10−19 W.
- 11M.1.SL.TZ1.21: An electron passes the north pole of a bar magnet as shown below. What is the direction of...
- 11M.1.SL.TZ1.18: A battery of internal resistance 2 Ω is connected to an external resistance of 10 Ω. The...
- 11M.1.HL.TZ1.22: A positively charged particle follows a circular path as shown below. Which of the...
- 11M.2.SL.TZ1.2a: The electron’s path while in the region of magnetic field is a quarter circle. Show that...
- 11M.2.SL.TZ1.8b: A battery of emf ε and negligible internal resistance is connected in series to two...
- 11M.2.SL.TZ1.8c: The graph shows the I-V characteristics of two conductors, X and Y. On the axes below,...
- 11M.2.SL.TZ1.8d: The conductors in (c) are connected in series to a battery of emf ε and negligible...
- 11M.2.SL.TZ1.8a: Define (i) electromotive force (emf ) of a battery. (ii) electrical resistance of a...