9702_w19_qp_42
A paper of Physics, 9702
Questions:
12
Year:
2019
Paper:
4
Variant:
2
Login to start this paper & get access to powerful tools
1
State Newton’s law of gravitation. The astronomer Johannes Kepler showed that the period T of rotation of a planet about the Sun is related to its mean distance R from the centre of the Sun by the expression R 3 T 2 = k where k is a constant. Use Newton’s law to show that, for planets in circular orbits about the Sun of mass M, the constant k is given by k = GM 4π 2 where G is the gravitational constant. Explain your working. A satellite is in a circular orbit about Mars. The radius of the orbit of the satellite is 4.38 × 106 m. The orbital period is 2.44 hours. Use the expressions in to calculate a value for the mass of Mars. mass = kg
13. Gravitational fields  →  13.2. Gravitational force between point masses
13. Gravitational fields  →  13.3. Gravitational field of a point mass
Open
2
Smoke particles are suspended in still air. Brownian motion of the smoke particles is seen through a microscope. Describe: what is seen through the microscope how Brownian motion provides evidence for the nature of the movement of gas molecules. A fixed mass of an ideal gas has volume 2.40 × 103 cm3 at pressure 3.51 × 105 Pa and temperature 290 K. The gas is heated at constant volume until the temperature is 310 K at pressure 3.75 × 105 Pa, as illustrated in . 2.40 × 103 cm3 3.51 × 105 Pa 290 K 2.40 × 103 cm3 3.75 × 105 Pa 310 K The quantity of thermal energy required to raise the temperature of 1.00 mol of the gas by 1.00 K at constant volume is 12.5 J. Calculate, to three significant figures: the amount, in mol, of the gas amount = mol the thermal energy transfer during the change. energy transfer = J For the change in the gas in , state: the quantity of external work done on the gas work done = J the change in internal energy, with the direction of this change. change = J direction
16. Thermodynamics  →  16.2. The first law of thermodynamics
15. Ideal gases  →  15.3. Kinetic theory of gases
Open
3
State what is meant by specific latent heat. A student uses the apparatus illustrated in to determine a value for the specific latent heat of fusion of ice. A V beaker melted ice pan of balance heater ice The balance reading measures the mass of the beaker and the melted ice in the beaker. The heater is switched on and pieces of ice at 0 °C are added continuously to the funnel so that the heater is always surrounded by ice. When water drips out of the funnel at a constant rate, the balance reading is noted at 2.0 minute intervals. After 10 minutes, the current in the heater is increased and the balance readings are taken for a further 12 minutes. From time 0 to time 10.0 minutes, 65 g of ice is melted. Use to determine the mass of ice melted from time 12.0 minutes to time 22.0 minutes. mass = g Explain why, although the power of the heater is changed, the rate at which thermal energy is transferred from the surroundings to the ice is constant. Determine a value for the specific latent heat of fusion L of ice. L = J g–1 Calculate the rate at which thermal energy is transferred from the surroundings to the ice. rate = W
14. Temperature  →  14.3. Specific heat capacity and specific latent heat
16. Thermodynamics  →  16.2. The first law of thermodynamics
Open
4
A ball of mass M is held on a horizontal surface by two identical extended springs, as illustrated in . ball mass M oscillator fixed point One spring is attached to a fixed point. The other spring is attached to an oscillator. The oscillator is switched off. The ball is displaced sideways along the axis of the springs and is then released. The variation with time t of the displacement x of the ball is shown in . –1.5 –1.0 –0.5 0.5 1.0 1.5 0.4 0.8 1.2 1.6 2.0 2.4 t / s x / cm State: what is meant by damping the evidence provided by that the motion of the ball is damped. The acceleration a and the displacement x of the ball are related by the expression – 2 a M k x = c m where k is the spring constant of one of the springs. The mass M of the ball is 1.2 kg. Use data from to determine the angular frequency ω of the oscillations of the ball. ω = rad s–1 Use your answer in to determine the value of k. k = N m–1 The oscillator is switched on. The amplitude of oscillation of the oscillator is constant. The angular frequency of the oscillations is gradually increased from 0.7ω to 1.3ω, where ω is the angular frequency calculated in . On the axes of , show the variation with angular frequency of the amplitude A of oscillation of the ball. A 0.7ω 1.0 angular frequency ω 1.3ω Some sand is now sprinkled on the horizontal surface. The angular frequency of the oscillations is again gradually increased from 0.7ω to 1.3ω. State two changes that occur to the line you have drawn on . 1. 2.
17. Oscillations  →  17.1. Simple harmonic oscillations
17. Oscillations  →  17.3. Damped and forced oscillations, resonance
Open
5
State what is meant by the specific acoustic impedance of a medium. The density of a sample of bone is 1.8 g cm–3 and the speed of ultrasound in the bone is 4.1 × 103 m s–1. Calculate the specific acoustic impedance ZB of the sample of bone. ZB = kg m–2 s–1 A parallel beam of ultrasound passes normally through a layer of fat and of muscle, as illustrated in . beam of ultrasound transmitted beam of ultrasound fat muscle 0.45 cm 2.1 cm (not to scale) The fat has thickness 0.45 cm and the muscle has thickness 2.1 cm. Data for fat and for muscle are given in . specific acoustic impedance Z / 106 kg m–2 s–1 linear attenuation coefficient μ / cm–1 fat muscle 1.3 1.7 0.24 0.23 The intensity reflection coefficient α at a boundary between two media of specific acoustic impedances Z1 and Z2 is given by the expression α = ( ) ( ) Z Z Z Z - + . Calculate the fraction of the intensity of the ultrasound that is transmitted through the boundary between the fat and the muscle. fraction transmitted = State what is meant by attenuation of an ultrasound wave. Data for linear attenuation coefficients are given in . Determine the ratio intensity of ultrasound transmitted through the medium intensity of ultrasound entering the medium for: 1. the layer of fat of thickness 0.45 cm ratio = 2. the layer of muscle of thickness 2.1 cm. ratio = Use your answers in and to determine the fraction of the intensity entering the layer of fat that is transmitted through the layer of muscle. fraction transmitted =
24. Medical physics  →  24.1. Production and use of ultrasound
Open
8
Electrons enter a rectangular slice PQRSEFGH of a semiconductor material at right-angles to face PQFE, as shown in . magnetic field flux density B direction of incident electrons S R G Q H F E P A uniform magnetic field of flux density B is directed into the slice, at right-angles to face PQRS. The electrons each have charge –q and drift speed v in the slice. State the magnitude and the direction of the force due to the magnetic field on each electron as it enters the slice. The force on the electrons causes a voltage VH to be established across the semiconductor slice given by the expression VH = BI ntq where I is the current in the slice. State the two faces between which the voltage VH is established. face and face Use letters from to identify the distance t. Aluminium (27 13 Al ) has a density of 2.7 g cm–3. Assume that there is one free electron available to carry charge per atom of aluminium. Show that the number of charge carriers per unit volume in aluminium is 6.0 × 1028 m–3. A sample of aluminium foil has a thickness of 0.090 mm. The current in the foil is 4.6 A. A uniform magnetic field of flux density 0.15 T acts at right-angles to the foil. Use the value in to calculate the voltage VH that is generated. VH = V
20. Magnetic fields  →  20.3. Force on a moving charge
9. Electricity  →  9.1. Electric current
20. Magnetic fields  →  20.4. Magnetic fields due to currents
Open
9
Define what is meant by electric potential at a point. In an α-particle scattering experiment, α-particles are directed towards a thin film of gold, as illustrated in . beam of α-particles gold film The apparatus is in a vacuum. The gold-197 (197 79 Au) nuclei in the film may be considered to be fixed point charges. The α-particles emitted from the source each have an energy of 4.8 MeV. Calculate: the initial kinetic energy EK, in J, of an α-particle emitted from the source EK = J the distance d of closest approach of an α-particle to a gold nucleus. d = m Use your answer in to comment on the possible diameter of a gold nucleus.
18. Electric fields  →  18.5. Electric potential
11. Particle physics  →  11.1. Atoms, nuclei and radiation
Open
10
The upper electron energy bands in an intrinsic semiconductor material are illustrated in . conduction band forbidden band valence band Use band theory to explain why the resistance of an intrinsic semiconductor material decreases as its temperature increases. A comparator circuit incorporating an ideal operational amplifier (op-amp) is shown in . +3.0 V 1.50 kΩ 1.20 kΩ 1.76 kΩ +5 V –5 V RT VOUT The variation with temperature θ of the resistance RT of the thermistor is shown in . 1.0 / °C RT / kΩ 1.5 2.0 2.5 3.0 3.5 θ Determine the temperature at which the light-emitting diode (LED) in switches on or off. temperature = °C State and explain whether the thermistor is above or below the temperature calculated in for the LED to emit light.
9. Electricity  →  9.3. Resistance and resistivity
10. D.C. circuits  →  10.3. Potential dividers
Open
11
State Faraday’s law of electromagnetic induction. A solenoid S has a small coil C placed near to one of its ends, as shown in . solenoid S 3.6 × 10–2 m coil C 63 turns The coil C has a circular cross-section of diameter 3.6 × 10–2 m and contains 63 turns of wire. The solenoid S produces a uniform magnetic field of flux density B, in tesla, in the region of coil C given by the expression B = 9.4 × 10–4 I where I is the current, in ampere, in the solenoid S. The variation with time t of the current I in solenoid S is shown in . t1 t2 t3 t4 t5 t6 t7 time t current I State two times at which: there is no electromotive force (e.m.f.) induced in coil C time and time the induced e.m.f. in coil C is a maximum but with opposite polarities. time and time The alternating current in the solenoid S in is replaced by a constant current of 5.0 A. Calculate the average e.m.f. induced in coil C when the current in solenoid S is reversed in a time of 6.0 ms. e.m.f. induced = V
20. Magnetic fields  →  20.5. Electromagnetic induction
20. Magnetic fields  →  20.4. Magnetic fields due to currents
Open