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An astrophysical model suggests that the drag force \( F \) acting on a cosmic dust grain is given by the equation:

\[ F = \Gamma \frac{G M \rho}{r} \]

where \( G \) is the gravitational constant, \( M \) is the mass of a nearby star, \( \rho \) is the density of the surrounding interstellar medium, and \( r \) is the distance from the star.

What are the SI base units of the constant \( \Gamma \)?

A stone is thrown vertically upwards from the edge of a vertical cliff of height \( h \). The stone is thrown with an initial speed \( v \) and eventually lands on the ground at the base of the cliff. The total flight time of the stone is \( t \).

If air resistance is negligible, and \( g \) is the acceleration of free fall, which equation correctly relates \( h \), \( v \), \( t \) and \( g \)?

A small object of weight \( W \) is suspended in equilibrium by two light, flexible strings. One string is at an angle of \( 35^\circ \) to the vertical, and the other string is horizontal.

What is the tension in the horizontal string?

Two wires, X and Y, are made of the same metal. Wire X has length \( L \) and diameter \( d \). Wire Y has length \( 2L \) and diameter \( 2d \).

Both wires are subjected to the same tensile force \( F \), which causes them to stretch elastically.

What is the ratio of the tensile strain in wire X to the tensile strain in wire Y?

A progressive transverse wave of frequency \( 25\text{ Hz} \) travels along a stretched horizontal string. The phase difference between two particles on the string that are separated by a horizontal distance of \( 0.15\text{ m} \) is \( \frac{\pi}{3}\text{ rad} \).

What is the speed of the wave?

A uniform metal wire of resistance \( R \) is stretched such that its length increases by \( 10\% \).

Assuming that both the density and the resistivity of the metal remain constant during stretching, what is the new resistance of the wire?

A hypothetical meson has a net charge of \( +1e \) and contains a strange antiquark (\( \bar{\text{s}} \)).

Which of the following could be the other quark in the meson?

In a double-slit interference experiment, light of wavelength \( \lambda \) passes through two slits separated by a distance \( a \) to produce bright fringes of spacing \( x \) on a screen at a distance \( D \) from the slits.

The experiment is now modified: the slit separation is doubled, and the distance from the slits to the screen is halved.

What wavelength of light must be used to keep the fringe spacing \( x \) unchanged?

A uniform picture frame of weight \(W\) and width \(d\) is suspended symmetrically from a smooth peg by a light inextensible string of total length \(L\), where \(L > d\). The ends of the string are attached to the top two corners of the frame. What is the tension \(T\) in the string?

A particle of mass \(m\) undergoes simple harmonic motion with amplitude \(A\) and period \(T\). Which expression gives the maximum net force acting on the particle during its motion?

A ball is thrown vertically upwards from the edge of a cliff with an initial speed of \(u\). After reaching its maximum height, it falls past the cliff edge and hits the ground at the base of the cliff with speed \(3u\). Air resistance is negligible. What is the height of the cliff?

A car of mass \(m\) travels up a slope angled at \(\theta\) to the horizontal at a constant speed \(v\). The resistive forces opposing the motion of the car are constant and equal to \(F\). What is the useful power output of the car’s engine?

In a double-slit experiment, light of wavelength \(\lambda\) is incident on two parallel slits of separation \(d\). Fringes of spacing \(x\) are observed on a screen at a distance \(D\) from the slits. If the wavelength of the light is halved, the slit separation is doubled, and the distance to the screen is tripled, what is the new fringe spacing?

A wire of length \(L\) and cross-sectional area \(A\) is made of a material of resistivity \(\rho\). The wire is stretched uniformly so that its length increases by \(10\%\) while its volume remains constant. What is the percentage increase in the electrical resistance of the wire?

A steel wire of length \(2.0\text{ m}\) and cross-sectional area \(1.5 \times 10^{-6}\text{ m}^2\) has a Young modulus of \(2.0 \times 10^{11}\text{ Pa}\). A load of \(150\text{ N}\) is suspended vertically from the wire, causing it to deform elastically. What is the strain energy stored in the wire?

A spacecraft of mass \(M\) is travelling in deep space at a constant velocity \(v\). An internal explosion splits the spacecraft into two fragments. One fragment of mass \(0.20 M\) is moving directly backwards with a speed of \(2.0 v\) relative to a stationary observer. What is the speed of the other fragment relative to the same stationary observer?

The rate of heat flow \( P \) (in \(\text{W}\)) through a solid rod of length \( L \) and cross-sectional area \( A \) is given by the equation: \( P = \frac{k A \Delta T}{L} \), where \( \Delta T \) is the temperature difference across the rod (measured in kelvin, \(\text{K}\)) and \( k \) is the thermal conductivity of the material. What are the SI base units of thermal conductivity \( k \)?

An object X is dropped from rest from a height of \( 80\text{ m} \) above the ground. At the same instant, object Y is thrown vertically upwards from ground level with an initial speed \( u \). The two objects pass each other at a height of \( 30\text{ m} \) above the ground. Air resistance is negligible. Take the acceleration of free fall \( g \) to be \( 9.81\text{ m s}^{-2} \). What is the initial speed \( u \) of object Y?

Two wires, P and Q, are made of the same material. Wire P has length \( L \) and diameter \( d \). Wire Q has length \( 2L \) and diameter \( 2d \). Wire P supports a load of weight \( F \), which produces an extension \( x \). What weight must be supported by wire Q to produce an extension of \( 2x \)? (Assume both wires behave elastically).

A sphere of mass \( m \) is moving to the right with speed \( 2v \). It undergoes a head-on, perfectly elastic collision with a sphere of mass \( 3m \) moving to the left with speed \( v \). What are the velocities of the two spheres after the collision?

In a double-slit experiment, monochromatic light of wavelength \( 600\text{ nm} \) is incident on two slits separated by a distance \( a \). Interference fringes are observed on a screen at a distance \( D \) from the slits. The distance between adjacent bright fringes is \( 1.2\text{ mm} \). The light source is then replaced by another source of wavelength \( \lambda \), and the slit separation is halved, while the screen distance remains unchanged. The new fringe separation is \( 1.6\text{ mm} \). What is the wavelength \( \lambda \) of the second light source?

Two wires, X and Y, have the same mass and are made of metals with densities \( d_X \) and \( d_Y \) respectively. The resistivity of metal X is \( \rho_X \) and the resistivity of metal Y is \( \rho_Y \). Wire X has twice the length of wire Y. What is the ratio of the resistance of wire X to the resistance of wire Y, \( \frac{R_X}{R_Y} \)?

A cell of electromotive force (e.m.f.) \( E \) and internal resistance \( r \) is connected to a variable external resistor of resistance \( R \). When \( R = 4.0\ \Omega \), the terminal potential difference across the cell is \( 3.0\text{ V} \). When \( R \) is increased to \( 9.0\ \Omega \), the terminal potential difference becomes \( 4.5\text{ V} \). What are the values of \( E \) and \( r \)?

A nucleus of Carbon-11 (\( ^{11}_{6}\text{C} \)) decays by \( \beta^+ \) emission to a nucleus of Boron-11 (\( ^{11}_{5}\text{B} \)). Which row correctly describes the change in quark composition of the decaying nucleon and the leptons produced during this process?

What is the SI base unit of electrical resistivity?

A model rocket is launched vertically upwards from the ground. It accelerates uniformly from rest at \(4.0\text{ m s}^{-2}\) for \(5.0\text{ s}\). The fuel is then completely exhausted, and the rocket continues to move upwards under the influence of gravity alone (air resistance is negligible). What is the maximum height above the ground reached by the rocket?

A block of mass \(3.0\text{ kg}\) slides along a frictionless horizontal surface at \(4.0\text{ m s}^{-1}\) and collides with a second block of mass \(1.0\text{ kg}\) which is initially at rest. The collision is perfectly elastic.

What are the speeds of the two blocks after the collision?

A uniform rigid bar of length \(2.0\text{ m}\) and weight \(80\text{ N}\) is hinged at one end to a vertical wall. The bar is held horizontally by a cable attached to its other end. The cable makes an angle of \(35^\circ\) with the horizontal bar.

What is the tension in the cable?

A wire of length \(L\) and cross-sectional area \(A\) is made of a metal of Young modulus \(E\). Under a tensile force \(F\), the wire extends by \(x\).

A second wire made of the same metal has length \(2L\) and a diameter twice that of the first wire.

What is the extension of this second wire when subjected to the same tensile force \(F\)?

In a double-slit interference experiment using red laser light of wavelength \(650\text{ nm}\), the interference pattern is observed on a screen placed at a distance of \(1.5\text{ m}\) from the slits. The distance between the centers of the two slits is \(0.30\text{ mm}\).

What is the distance between adjacent bright fringes on the screen?

A potential difference of \(6.0\text{ V}\) is applied across a uniform resistance wire of length \(2.0\text{ m}\) and cross-sectional area \(1.5 \times 10^{-7}\text{ m}^2\). The current in the wire is \(0.80\text{ A}\).

What is the resistivity of the metal from which the wire is made?

A baryon has a net charge of \(+e\) and a strangeness of \(-1\).

Knowing that the strange quark (\(s\)) has a charge of \(-\frac{1}{3}e\) and a strangeness of \(-1\), and that the baryon contains only up (\(u\)), down (\(d\)), and strange (\(s\)) quarks, what is the quark composition of this baryon?

A stone is projected vertically upwards with speed \(v\) from a cliff of height \(H\). It hits the ground at the base of the cliff with speed \(3v\). Air resistance is negligible. What is the maximum height reached by the stone above its starting point?

A uniform rigid beam of weight \(W\) and length \(L\) is held horizontally by a hinge at one end and a light cable attached to the other end. The cable makes an angle of \(30^\circ\) with the horizontal beam. What is the magnitude of the horizontal component of the force exerted by the hinge on the beam?

Two wires \(P\) and \(Q\) are made of the same metal. Wire \(P\) has twice the diameter and half the length of wire \(Q\). Both wires are suspended vertically and support identical loads, which stretch them elastically. What is the ratio \(\frac{\text{strain in } P}{\text{strain in } Q}\)?

A cell of electromotive force (e.m.f.) \(E\) and internal resistance \(r\) is connected to a variable resistor of resistance \(R\). A voltmeter is connected across the terminals of the cell. As the resistance \(R\) is increased from a very low value to a very high value, how do the current \(I\) in the circuit and the terminal potential difference \(V\) measured by the voltmeter change?

In a double-slit interference experiment using light of wavelength \(600\text{ nm}\), the fringe separation on a screen placed at a fixed distance from the slits is \(1.2\text{ mm}\). If the light source is replaced by one of wavelength \(450\text{ nm}\) and the slit separation is halved, what is the new fringe separation?

Two balls, X and Y, travel along a frictionless horizontal track. Ball X of mass \(2m\) moving with velocity \(u\) collides head-on with ball Y of mass \(m\) moving in the opposite direction with velocity \(2u\). The collision is perfectly elastic. What are the velocities of X and Y after the collision (taking the direction of the initial velocity of X as positive)?

A metal wire of resistance \(R\) is stretched such that its length increases by \(10\%\) while its volume remains constant. What is the percentage increase in the resistance of the wire?

A particle known as a kaon has a quark composition of \(u\bar{s}\), where \(u\) represents an up quark and \(\bar{s}\) represents an antistrange quark. What are the electric charge of this kaon (in terms of the elementary charge \(e\)) and its hadron classification?

A uniform metal rod of length 1.5 m and weight 45 N is pivoted at one end to a vertical wall. The rod is held horizontally by a wire attached to the other end of the rod. The wire makes an angle of \(30^\circ\) with the horizontal rod. (a) Define center of gravity. (b) By taking moments about the pivot, calculate the tension in the wire. (c) Calculate the vertical component of the force exerted on the rod by the pivot.

An object of mass 0.20 kg undergoes simple harmonic motion. The displacement x of the object varies with time t according to the equation \(x = 0.050 \cos(8.0 t)\), where x is in meters and t is in seconds. (a) State the two conditions required for a system to undergo simple harmonic motion. (b) Calculate the maximum kinetic energy of the object. (c) Determine the magnitude of the acceleration of the object when its displacement is 0.030 m.

A ball is projected horizontally from the top of a cliff of height 45 m with an initial horizontal velocity of \(12\text{ m s}^{-1}\). Air resistance is negligible. (a) Calculate the time taken for the ball to reach the ground. (b) Calculate the horizontal distance traveled by the ball before it hits the ground. (c) Determine the magnitude and direction of the velocity of the ball just as it strikes the ground.

An electric motor is used to lift a load of mass 80 kg vertically upwards through a height of 15 m in a time of 6.0 s. The electrical power input to the motor is 2.5 kW. (a) Calculate the useful work done in lifting the load. (b) Calculate the useful output power of the motor. (c) Determine the efficiency of the motor.

Laser light of wavelength 632 nm is incident normally on a double slit. The slit separation is 0.25 mm. Interference fringes are observed on a screen placed parallel to the double slit at a distance of 1.8 m. (a) State what is meant by coherent light sources. (b) Calculate the fringe separation observed on the screen. (c) Describe the effect on the fringe separation if the wavelength of the light is increased to 700 nm while keeping all other parameters constant.

A uniform copper wire of length 2.0 m and cross-sectional area \(1.2 \times 10^{-7}\text{ m}^2\) has a resistance of \(0.28\ \Omega\). (a) Calculate the resistivity of copper. (b) The wire is stretched uniformly until its length becomes 3.0 m. Assuming the volume and resistivity of the wire remain constant, calculate the new resistance of the wire.

A free neutron decays into a proton, an electron, and an electron antineutrino. (a) Write down the balanced nuclear equation representing this decay, including the nucleon numbers and proton numbers for all particles. (b) State the quark composition of a neutron and a proton. (c) Describe the change in quark composition that occurs during this decay.

**Paper 31 Practical Skills — Question 1 (20 marks)**

**An investigation into the vertical oscillations of a pivoted wooden rod.**

In this experiment, you will investigate how the period of oscillation of a wooden rod depends on the position of its supporting spring.

**Apparatus:**
- Retort stand, boss, and clamp
- G-clamp or heavy weight to secure the stand
- A second retort stand, boss, and clamp
- A wooden rod (e.g., a half-metre rule) with a small hole drilled near the 0.0 cm mark to act as a pivot
- A nail or pin to act as a pivot axis through the hole, clamped securely
- A spring (spring constant approximately \( 25 \text{ N m}^{-1} \))
- A 100 g mass, taped securely to the free end of the rod (at the 50.0 cm mark)
- A stopwatch
- A metre rule

**Procedure:**
1. Set up the apparatus. Clamp one end of the wooden rod using the pivot pin so that the rod can rotate freely in a vertical plane. Connect the spring between the second clamp and a loop of thread situated at a distance \( d \) from the pivot. Adjust the height of the second clamp so that the wooden rod is horizontal. Ensure the 100 g mass is firmly taped to the end of the rod.

2. Measure and record the distance \( d \) from the pivot to the spring attachment point. The value of \( d \) should initially be approximately 15.0 cm.

3. Displace the free end of the rod vertically downwards by a small distance and release it so that it performs vertical oscillations. Measure and record the time \( t \) for 10 complete oscillations. Repeat this measurement to obtain a second reading for \( t \), and calculate the mean time \( t_{\text{mean}} \). Determine the period \( T \) of the oscillations.

4. Change \( d \) by moving the spring attachment loop along the rod. Adjust the height of the second clamp to keep the rod horizontal. Repeat step 3 for five further values of \( d \) in the range \( 15.0 \text{ cm} \le d \le 45.0 \text{ cm} \).

5. Record all six sets of values for \( d \), \( t_1 \), \( t_2 \), \( t_{\text{mean}} \), and \( T \) in a table. Include columns for \( d^2 \) and \( T^{-2} \).

6. Plot a graph of \( T^{-2} \) on the y-axis against \( d^2 \) on the x-axis. Draw the straight line of best fit.

7. Determine the gradient and y-intercept of this line.

8. The quantities \( T \) and \( d \) are related by the equation:
\( \frac{1}{T^2} = p d^2 + q \)
where \( p \) and \( q \) are constants. Use your answers from part 7 to determine the values of \( p \) and \( q \). Include appropriate units for both constants.

9. The spring constant \( k \) of the spring is related to the constant \( p \) by the formula:
\( p = \frac{k}{4 \pi^2 m} \)
where \( m = 0.100 \text{ kg} \) is the mass attached to the end of the rod. Calculate the value of \( k \), giving its unit.

**Paper 31 Practical Skills — Question 2 (20 marks)**

**An investigation into the deflection of a loaded wooden rule supported by a spring.**

In this experiment, you will investigate how the deflection of a horizontal wooden rule depends on the position of a load suspended from it.

**Apparatus:**
- Metre rule (to be used as the cantilever)
- Stand, boss, and clamp to clamp one end of the metre rule horizontally (at the 0.0 cm mark)
- A second stand, boss, and clamp to support the top of a spring
- A spring (spring constant approximately \( 10 \text{ to } 15 \text{ N m}^{-1} \))
- A 100 g mass hanger or mass with a hook
- A half-metre rule (for vertical height measurements)
- A set-square to ensure vertical measurements

**Procedure:**
1. Set up the apparatus. Clamp the metre rule horizontally at its 0.0 cm mark. Attach the spring vertically between the second clamp and a loop of thread placed at the 40.0 cm mark of the metre rule. Adjust the height of the second clamp so that the rule is horizontal.

2. (a) Measure and record the unstretched length \( L_0 \) of the spring (the length of the coiled section) to the nearest millimetre.

(b) Measure and record the vertical height \( h_0 \) of the 50.0 cm mark of the horizontal metre rule above the surface of the bench.

3. (c) Suspend a 100 g mass from the metre rule at a distance \( x = 45.0 \text{ cm} \) from the clamped end (the pivot). Measure and record the new vertical height \( h \) of the 50.0 cm mark of the rule above the bench. Calculate the vertical deflection \( z = h_0 - h \).

4. (d) Estimate the percentage uncertainty in your value of \( z \). Show your working.

5. (e) Move the 100 g mass to a position \( x = 25.0 \text{ cm} \) from the clamped end. Measure and record the new height \( h \) of the 50.0 cm mark above the bench. Calculate the new vertical deflection \( z \).

6. (f) It is suggested that the deflection \( z \) and position \( x \) are related by the equation:
\( z = C x \)
where \( C \) is a constant.
(i) Calculate two values of \( C \) using your measurements.
(ii) Explain whether your results support the suggested relationship. State a clear criterion for your decision and show your calculations.
(iii) The spring constant \( k \) of the spring can be estimated from the relationship:
\( k = \frac{m g L}{C d^2} \)
where \( m = 0.100 \text{ kg} \), \( g = 9.81 \text{ m s}^{-2} \), \( L = 0.500 \text{ m} \), and \( d = 0.400 \text{ m} \). Using your second value of \( C \) (with \( x \) converted to metres), calculate the spring constant \( k \). Include its unit.

7. (g) Describe the limitations and sources of error in this experiment. Suggest improvements that could be made to improve the accuracy. You should list four distinct limitations and four corresponding improvements.