Option A: Relativity (Core topics)

State whether the field around the wire according to observer X is electric, magnetic or a combination of both.

Deduce whether the overall field around the wire is electric, magnetic or a combination of both according to observer Y.

Calculate, according to Galilean relativity, the time taken for a muon to travel to the ground.

Deduce why only a small fraction of the total number of muons created is expected to be detected at ground level according to Galilean relativity.

Calculate, for the reference frame of rocket A, the speed of rocket B according to the Galilean transformation.

explain why the time coordinate of E in frame S is $t=\frac{L}{c}$.

hence show that the space coordinate of E in frame S is $x=L+\frac{vL}{c}$.

Determine the time it takes the probe to reach the front of the rocket according to an observer at rest in the rocket.

Use your answer to (a)(ii) to describe the paradigm shift that Einstein’s theory of special relativity produced.

Estimate in the Earth frame the fraction of the original muons that will reach the Earth’s surface before decaying according to Newtonian mechanics.

Deduce, using your answer to part (a), the nature of the force that acts on the particle P in the rest frame of P.

Explain how the force in part (b)(ii) arises.

The designers state that the energy transferred by the resistor every second is 15 J.

Calculate the current in the resistor.

A variable resistor is connected to a cell with emf ε and internal resistance r as shown. When the current in the circuit is I, the potential difference measured across the terminals of the cell is V.

The resistance of the variable resistor is doubled.

What is true about the current and the potential difference?

Two resistors of equal resistance R are connected with two cells of emf ε and 2ε. Both cells have negligible internal resistance.

What is the current in the resistor labelled X?

A.  $\frac{\epsilon }{2R}$

B.  $\frac{3\epsilon }{2R}$

C.  $\frac{\epsilon }{R}$

D.  $\frac{3\epsilon }{R}$

An electron is accelerated from rest through a potential difference V.

What is the maximum speed of the electron?

A.  $\sqrt{\frac{2eV}{m_e}}$

B.  $\frac{eV}{m_e}$

C.  $\frac{2eV}{m_e}$

D.  $\sqrt{\frac{2V}{m_e}}$

A cell of negligible internal resistance and electromotive force (emf) 6.0 V is connected to three resistors R, P and Q.

R is an ohmic resistor. The I-V characteristics of P and Q are shown in the graph.

The current in P is 0.40 A.

A cell of negligible internal resistance and electromotive force (emf) 6.0 V is connected to three resistors R, P and Q.

R is an ohmic resistor. The I-V characteristics of P and Q are shown in the graph.

The current in P is 0.40 A.

Explain, by reference to Faraday’s law of electromagnetic induction, why there is an electromotive force (emf) induced in the loop as it leaves the region of magnetic field.

P and Q are two conductors of the same material connected in series. Q has a diameter twice that of P.

What is $\frac{\mathrm{drift} \mathrm{speed} \mathrm{of} \mathrm{electrons} \mathrm{in} \mathrm{P}}{\mathrm{drift} \mathrm{speed} \mathrm{of} \mathrm{electrons} \mathrm{in} \mathrm{Q}}$?

A.  4

B.  2

C.  $\frac{1}{2}$

D.  $\frac{1}{4}$

Three lamps (X, Y and Z) are connected as shown in the circuit. The emf of the cell is 20 V. The internal resistance of the cell is negligible. The power dissipated by X, Y and Z is 10 W, 20 W and 20 W respectively.

What is the voltage across Lamp X and Lamp Y?

P and R are parallel wires carrying the same current into the plane of the paper. P and R are equidistant from a point Q. The line PQ is perpendicular to the line RQ.

The magnetic field due to P at Q is $X$. What is the magnitude of the resultant magnetic field at Q due to both wires?

A.  $\frac{X}{2}$

B.  $X$

C.  $X\sqrt{2}$

D.  $2X$

A negatively charged particle is stationary halfway between two horizontal charged plates. The plates are separated by a distance d with potential difference V between them.

What is the magnitude of the electric field and direction of the electric field at the position of the particle?

The designers state that the energy transferred by the resistor every second is 15 J.

Calculate the current in the resistor.

X and Y are two conductors with the same diameter, made from the same material. Y is twice the length of X. They are connected in series to a cell of emf ε.

X dissipates power P.

What is the power dissipated by Y?

A.  $\frac{P}{2}$

B.  P

C.  2P

D.  4P

Four identical lamps are connected in a circuit. The current through lamp L is I.

The lamps are rearranged using the same cell.

What is the current through L?

A.  $\frac{I}{4}$

B.  $\frac{I}{2}$

C.  I

D.  2I

Two resistors of equal resistance R are connected with two cells of emf ε and 2ε. Both cells have negligible internal resistance.

What is the current in the resistor labelled X?

A.  $\frac{\epsilon }{2R}$

B.  $\frac{3\epsilon }{2R}$

C.  $\frac{\epsilon }{R}$

D.  $\frac{3\epsilon }{R}$

Use your answer to (a)(ii) to describe the paradigm shift that Einstein’s theory of special relativity produced.

Use your answer to (a)(ii) to describe the paradigm shift that Einstein’s theory of special relativity produced.

Estimate in the Earth frame the fraction of the original muons that will reach the Earth’s surface before decaying according to Newtonian mechanics.

Estimate in the Earth frame the fraction of the original muons that will reach the Earth’s surface before decaying according to Newtonian mechanics.

Deduce, using your answer to part (a), the nature of the force that acts on the particle P in the rest frame of P.

Explain how the force in part (b)(ii) arises.

Deduce, using your answer to part (a), the nature of the force that acts on the particle P in the rest frame of P.

Explain how the force in part (b)(ii) arises.

The designers state that the energy transferred by the resistor every second is 15 J.

Calculate the current in the resistor.

The designers state that the energy transferred by the resistor every second is 15 J.

Calculate the current in the resistor.

A variable resistor is connected to a cell with emf ε and internal resistance r as shown. When the current in the circuit is I, the potential difference measured across the terminals of the cell is V.

The resistance of the variable resistor is doubled.

What is true about the current and the potential difference?

Two resistors of equal resistance R are connected with two cells of emf ε and 2ε. Both cells have negligible internal resistance.

What is the current in the resistor labelled X?

A.  $\frac{\epsilon }{2R}$

B.  $\frac{3\epsilon }{2R}$

C.  $\frac{\epsilon }{R}$

D.  $\frac{3\epsilon }{R}$

An electron is accelerated from rest through a potential difference V.

What is the maximum speed of the electron?

A.  $\sqrt{\frac{2eV}{m_e}}$

B.  $\frac{eV}{m_e}$

C.  $\frac{2eV}{m_e}$

D.  $\sqrt{\frac{2V}{m_e}}$

A cell of negligible internal resistance and electromotive force (emf) 6.0 V is connected to three resistors R, P and Q.

R is an ohmic resistor. The I-V characteristics of P and Q are shown in the graph.

The current in P is 0.40 A.

A cell of negligible internal resistance and electromotive force (emf) 6.0 V is connected to three resistors R, P and Q.

R is an ohmic resistor. The I-V characteristics of P and Q are shown in the graph.

The current in P is 0.40 A.

A cell of negligible internal resistance and electromotive force (emf) 6.0 V is connected to three resistors R, P and Q.

R is an ohmic resistor. The I-V characteristics of P and Q are shown in the graph.

The current in P is 0.40 A.

A cell of negligible internal resistance and electromotive force (emf) 6.0 V is connected to three resistors R, P and Q.

R is an ohmic resistor. The I-V characteristics of P and Q are shown in the graph.

The current in P is 0.40 A.

Explain, by reference to Faraday’s law of electromagnetic induction, why there is an electromotive force (emf) induced in the loop as it leaves the region of magnetic field.

Explain, by reference to Faraday’s law of electromagnetic induction, why there is an electromotive force (emf) induced in the loop as it leaves the region of magnetic field.

P and Q are two conductors of the same material connected in series. Q has a diameter twice that of P.

What is $\frac{\mathrm{drift} \mathrm{speed} \mathrm{of} \mathrm{electrons} \mathrm{in} \mathrm{P}}{\mathrm{drift} \mathrm{speed} \mathrm{of} \mathrm{electrons} \mathrm{in} \mathrm{Q}}$?

A.  4

B.  2

C.  $\frac{1}{2}$

D.  $\frac{1}{4}$

Three lamps (X, Y and Z) are connected as shown in the circuit. The emf of the cell is 20 V. The internal resistance of the cell is negligible. The power dissipated by X, Y and Z is 10 W, 20 W and 20 W respectively.

What is the voltage across Lamp X and Lamp Y?

P and R are parallel wires carrying the same current into the plane of the paper. P and R are equidistant from a point Q. The line PQ is perpendicular to the line RQ.

The magnetic field due to P at Q is $X$. What is the magnitude of the resultant magnetic field at Q due to both wires?

A.  $\frac{X}{2}$

B.  $X$

C.  $X\sqrt{2}$

D.  $2X$

A negatively charged particle is stationary halfway between two horizontal charged plates. The plates are separated by a distance d with potential difference V between them.

What is the magnitude of the electric field and direction of the electric field at the position of the particle?

The designers state that the energy transferred by the resistor every second is 15 J.

Calculate the current in the resistor.

The designers state that the energy transferred by the resistor every second is 15 J.

Calculate the current in the resistor.

X and Y are two conductors with the same diameter, made from the same material. Y is twice the length of X. They are connected in series to a cell of emf ε.

X dissipates power P.

What is the power dissipated by Y?

A.  $\frac{P}{2}$

B.  P

C.  2P

D.  4P

Four identical lamps are connected in a circuit. The current through lamp L is I.

The lamps are rearranged using the same cell.

What is the current through L?

A.  $\frac{I}{4}$

B.  $\frac{I}{2}$

C.  I

D.  2I

Two resistors of equal resistance R are connected with two cells of emf ε and 2ε. Both cells have negligible internal resistance.

What is the current in the resistor labelled X?

A.  $\frac{\epsilon }{2R}$

B.  $\frac{3\epsilon }{2R}$

C.  $\frac{\epsilon }{R}$

D.  $\frac{3\epsilon }{R}$

State whether the field around the wire according to observer X is electric, magnetic or a combination of both.

Deduce whether the overall field around the wire is electric, magnetic or a combination of both according to observer Y.

State whether the field around the wire according to observer X is electric, magnetic or a combination of both.

Deduce whether the overall field around the wire is electric, magnetic or a combination of both according to observer Y.

Calculate, according to Galilean relativity, the time taken for a muon to travel to the ground.

Deduce why only a small fraction of the total number of muons created is expected to be detected at ground level according to Galilean relativity.

Calculate, according to Galilean relativity, the time taken for a muon to travel to the ground.

Deduce why only a small fraction of the total number of muons created is expected to be detected at ground level according to Galilean relativity.

Calculate, for the reference frame of rocket A, the speed of rocket B according to the Galilean transformation.

Calculate, for the reference frame of rocket A, the speed of rocket B according to the Galilean transformation.

explain why the time coordinate of E in frame S is $t=\frac{L}{c}$.

hence show that the space coordinate of E in frame S is $x=L+\frac{vL}{c}$.

explain why the time coordinate of E in frame S is $t=\frac{L}{c}$.

hence show that the space coordinate of E in frame S is $x=L+\frac{vL}{c}$.

Determine the time it takes the probe to reach the front of the rocket according to an observer at rest in the rocket.

Determine the time it takes the probe to reach the front of the rocket according to an observer at rest in the rocket.

Identify the terms in the formula.

u′ = $\frac{u-v}{1-\frac{uv}{c^2}}$

Determine, according to an observer in A, the velocity of B.

Determine, according to an observer in A, the time taken for B to meet A.

Discuss the change in d according to observer Y.

Calculate, according to the theory of special relativity, the time taken for a muon to reach the ground in the reference frame of the muon.

Discuss how your result in (b)(i) and the outcome of the muon decay experiment support the theory of special relativity.

Explain whether or not the arrival times of the two flashes in the Earth frame are simultaneous events in the frame of rocket A.

Calculate the velocity of rocket B relative to rocket A.

Calculate, for the reference frame of rocket A, the speed of rocket B according to the Lorentz transformation.

Outline, with reference to special relativity, which of your calculations in (a) is more likely to be valid.

Calculate the velocity of the spaceship relative to the Earth.

The spaceship passes the space station 90 minutes later as measured by the spaceship clock. Determine, for the reference frame of the Earth, the distance between the Earth and the space station.

As the spaceship passes the space station, the space station sends a radio signal back to the Earth. The reception of this signal at the Earth is event A. Determine the time on the Earth clock when event A occurs.

Explain what is meant by the statement that the spacetime interval is an invariant quantity.

calculate the spacetime interval.

determine the time between them according to observer B.

Outline why the observed times are different for A and B.

Calculate the speed of the probe relative to the ground.

Determine the time it takes the probe to reach the front of the rocket according to an observer at rest on the ground.

x′ = 1.5 m.

ct′ = –1.1 m.

Estimate in the Earth frame the fraction of the original muons that will reach the Earth’s surface before decaying according to special relativity.

Demonstrate how an observer moving with the same velocity as the muons accounts for the answer to (a)(ii).

Show that the value of the invariant spacetime interval between events 1 and 2 is 9600 ly².

Explain how the force in part (b)(ii) arises.

The velocity of P is 0.30c relative to the laboratory. A second particle Q moves at a velocity of 0.80c relative to the laboratory.

Calculate the speed of Q relative to P.

Calculate, for observer A, the length L_A of the bridge

Calculate, for observer A, the time taken to cross the bridge.

Determine the time, according to observer A, between X and Y.

Deduce the length of the probe as measured by an observer in the spaceship.

Explain which of the lengths is the proper length.

Calculate the speed of the probe in terms of $c$, relative to Earth.

Calculate the speed of the probe in terms of $c$, relative to Earth.

According to laboratory observers $\frac{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{detected}}{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{produced}}=\frac{1}{2}$.

Calculate D.

According to laboratory observers $\frac{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{detected}}{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{produced}}=\frac{1}{2}$.

Calculate D.

Estimate in the Earth frame the fraction of the original muons that will reach the Earth’s surface before decaying according to special relativity.

Demonstrate how an observer moving with the same velocity as the muons accounts for the answer to (a)(ii).

Estimate in the Earth frame the fraction of the original muons that will reach the Earth’s surface before decaying according to special relativity.

Demonstrate how an observer moving with the same velocity as the muons accounts for the answer to (a)(ii).

Show that the value of the invariant spacetime interval between events 1 and 2 is 9600 ly².

Show that the value of the invariant spacetime interval between events 1 and 2 is 9600 ly².

Explain how the force in part (b)(ii) arises.

The velocity of P is 0.30c relative to the laboratory. A second particle Q moves at a velocity of 0.80c relative to the laboratory.

Calculate the speed of Q relative to P.

Explain how the force in part (b)(ii) arises.

The velocity of P is 0.30c relative to the laboratory. A second particle Q moves at a velocity of 0.80c relative to the laboratory.

Calculate the speed of Q relative to P.

Calculate, for observer A, the length L_A of the bridge

Calculate, for observer A, the time taken to cross the bridge.

Determine the time, according to observer A, between X and Y.

Calculate, for observer A, the length L_A of the bridge

Calculate, for observer A, the time taken to cross the bridge.

Determine the time, according to observer A, between X and Y.

Deduce the length of the probe as measured by an observer in the spaceship.

Explain which of the lengths is the proper length.

Calculate the speed of the probe in terms of $c$, relative to Earth.

Deduce the length of the probe as measured by an observer in the spaceship.

Explain which of the lengths is the proper length.

Calculate the speed of the probe in terms of $c$, relative to Earth.

Calculate the speed of the probe in terms of $c$, relative to Earth.

Identify the terms in the formula.

u′ = $\frac{u-v}{1-\frac{uv}{c^2}}$

Determine, according to an observer in A, the velocity of B.

Determine, according to an observer in A, the time taken for B to meet A.

Identify the terms in the formula.

u′ = $\frac{u-v}{1-\frac{uv}{c^2}}$

Determine, according to an observer in A, the velocity of B.

Determine, according to an observer in A, the time taken for B to meet A.

According to laboratory observers $\frac{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{detected}}{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{produced}}=\frac{1}{2}$.

Calculate D.

According to laboratory observers $\frac{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{detected}}{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{produced}}=\frac{1}{2}$.

Calculate D.

According to laboratory observers $\frac{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{detected}}{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{produced}}=\frac{1}{2}$.

Calculate D.

According to laboratory observers $\frac{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{detected}}{\mathrm{number} \mathrm{of} \mathrm{muons} \mathrm{produced}}=\frac{1}{2}$.

Calculate D.

Discuss the change in d according to observer Y.

Discuss the change in d according to observer Y.

Calculate, according to the theory of special relativity, the time taken for a muon to reach the ground in the reference frame of the muon.

Discuss how your result in (b)(i) and the outcome of the muon decay experiment support the theory of special relativity.

Calculate, according to the theory of special relativity, the time taken for a muon to reach the ground in the reference frame of the muon.

Discuss how your result in (b)(i) and the outcome of the muon decay experiment support the theory of special relativity.

Explain whether or not the arrival times of the two flashes in the Earth frame are simultaneous events in the frame of rocket A.

Calculate the velocity of rocket B relative to rocket A.

Explain whether or not the arrival times of the two flashes in the Earth frame are simultaneous events in the frame of rocket A.

Calculate the velocity of rocket B relative to rocket A.

Calculate, for the reference frame of rocket A, the speed of rocket B according to the Lorentz transformation.

Outline, with reference to special relativity, which of your calculations in (a) is more likely to be valid.

Calculate, for the reference frame of rocket A, the speed of rocket B according to the Lorentz transformation.

Outline, with reference to special relativity, which of your calculations in (a) is more likely to be valid.

Calculate the velocity of the spaceship relative to the Earth.

The spaceship passes the space station 90 minutes later as measured by the spaceship clock. Determine, for the reference frame of the Earth, the distance between the Earth and the space station.

As the spaceship passes the space station, the space station sends a radio signal back to the Earth. The reception of this signal at the Earth is event A. Determine the time on the Earth clock when event A occurs.

Calculate the velocity of the spaceship relative to the Earth.

The spaceship passes the space station 90 minutes later as measured by the spaceship clock. Determine, for the reference frame of the Earth, the distance between the Earth and the space station.

As the spaceship passes the space station, the space station sends a radio signal back to the Earth. The reception of this signal at the Earth is event A. Determine the time on the Earth clock when event A occurs.

Explain what is meant by the statement that the spacetime interval is an invariant quantity.

calculate the spacetime interval.

determine the time between them according to observer B.

Outline why the observed times are different for A and B.

Explain what is meant by the statement that the spacetime interval is an invariant quantity.

calculate the spacetime interval.

determine the time between them according to observer B.

Outline why the observed times are different for A and B.

Calculate the speed of the probe relative to the ground.

Determine the time it takes the probe to reach the front of the rocket according to an observer at rest on the ground.

Calculate the speed of the probe relative to the ground.

Determine the time it takes the probe to reach the front of the rocket according to an observer at rest on the ground.

x′ = 1.5 m.

ct′ = –1.1 m.

x′ = 1.5 m.

ct′ = –1.1 m.

For an observer on the train, it is the tunnel that is moving and therefore will appear length contracted. This seems to contradict the observation made by the observer at rest to the tunnel, creating a paradox. Explain how this paradox is resolved. You may refer to your spacetime diagram in (b).

Draw on the spacetime diagram the worldline of B according to the Earth observer and label it B.

Deduce, showing your working on the spacetime diagram, the value of ct according to the Earth observer at which the rocket B emitted its flash of light.

Construct event A and event B on the spacetime diagram.

Estimate, using the spacetime diagram, the time at which event B occurs for the spaceship.

Label, on the diagram, the event that has coordinates x′ = 1.0 m and ct′ = 0. Label this event with the letter Q.

Show, using the spacetime diagram, that the speed of the spaceship relative to the Earth is 0.80c.

Label, with the letter E, the event of the spaceship going past the planet.

Suggest whether the rocket launched by the spacecraft might be the cause of the explosion of the asteroid.

Using the spacetime diagram, determine which event occurred first for the spacecraft observer, event 1 or event 2.

Determine, using the diagram, the speed of the spacecraft relative to the galaxy.

Draw, on the spacetime diagram, the space axis for the reference frame of observer A. Label this axis $x$'.

Calculate in terms of $c$ the velocity of spaceship A relative to observer O.

Draw the $x\text{'}$ axis for the reference frame of spaceship A.

Plot the event E on the spacetime diagram and label it E.

Determine the time, according to spaceship A, when light from event E was observed on spaceship A.

Show, using the spacetime diagram, that the speed of the spaceship relative to the Earth is 0.80c.

Label, with the letter E, the event of the spaceship going past the planet.

Show, using the spacetime diagram, that the speed of the spaceship relative to the Earth is 0.80c.

Label, with the letter E, the event of the spaceship going past the planet.

Suggest whether the rocket launched by the spacecraft might be the cause of the explosion of the asteroid.

Using the spacetime diagram, determine which event occurred first for the spacecraft observer, event 1 or event 2.

Determine, using the diagram, the speed of the spacecraft relative to the galaxy.

Suggest whether the rocket launched by the spacecraft might be the cause of the explosion of the asteroid.

Using the spacetime diagram, determine which event occurred first for the spacecraft observer, event 1 or event 2.

Determine, using the diagram, the speed of the spacecraft relative to the galaxy.

Draw, on the spacetime diagram, the space axis for the reference frame of observer A. Label this axis $x$'.

Draw, on the spacetime diagram, the space axis for the reference frame of observer A. Label this axis $x$'.

Calculate in terms of $c$ the velocity of spaceship A relative to observer O.

Draw the $x\text{'}$ axis for the reference frame of spaceship A.

Plot the event E on the spacetime diagram and label it E.

Determine the time, according to spaceship A, when light from event E was observed on spaceship A.

Calculate in terms of $c$ the velocity of spaceship A relative to observer O.

Draw the $x\text{'}$ axis for the reference frame of spaceship A.

Plot the event E on the spacetime diagram and label it E.

Determine the time, according to spaceship A, when light from event E was observed on spaceship A.

For an observer on the train, it is the tunnel that is moving and therefore will appear length contracted. This seems to contradict the observation made by the observer at rest to the tunnel, creating a paradox. Explain how this paradox is resolved. You may refer to your spacetime diagram in (b).

For an observer on the train, it is the tunnel that is moving and therefore will appear length contracted. This seems to contradict the observation made by the observer at rest to the tunnel, creating a paradox. Explain how this paradox is resolved. You may refer to your spacetime diagram in (b).

Draw on the spacetime diagram the worldline of B according to the Earth observer and label it B.

Deduce, showing your working on the spacetime diagram, the value of ct according to the Earth observer at which the rocket B emitted its flash of light.

Draw on the spacetime diagram the worldline of B according to the Earth observer and label it B.

Deduce, showing your working on the spacetime diagram, the value of ct according to the Earth observer at which the rocket B emitted its flash of light.

Construct event A and event B on the spacetime diagram.

Estimate, using the spacetime diagram, the time at which event B occurs for the spaceship.

Construct event A and event B on the spacetime diagram.

Estimate, using the spacetime diagram, the time at which event B occurs for the spaceship.

Label, on the diagram, the event that has coordinates x′ = 1.0 m and ct′ = 0. Label this event with the letter Q.

Label, on the diagram, the event that has coordinates x′ = 1.0 m and ct′ = 0. Label this event with the letter Q.