Cambridge Assessment International Education

Cambridge International Advanced Subsidiary and Advanced Level

* 3 9 0 2 3 9 8 2 4 5 *

PHYSICS 9702/23
Paper 2 AS Level Structured Questions May/June 2019
1 hour 15 minutes
Candidates answer on the Question Paper.
No Additional Materials are required.

READ THESE INSTRUCTIONS FIRST

Write your centre number, candidate number and name on all the work you hand in.
Write in dark blue or black pen.
You may use an HB pencil for any diagrams or graphs.
Do not use staples, paper clips, glue or correction fluid.
DO NOT WRITE IN ANY BARCODES.

Answer all questions.

Electronic calculators may be used.

You may lose marks if you do not show your working or if you do not use appropriate units.

At the end of the examination, fasten all your work securely together.
The number of marks is given in brackets [ ] at the end of each question or part question.

This document consists of 14 printed pages and 2 blank pages.

DC (ST/CB) 162172/3
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Data

speed of light in free space c = 3.00 × 108 m s−1

permeability of free space μ0 = 4π × 10−7 H m−1

permittivity of free space ε0 = 8.85 × 10−12 F m−1

1
( = 8.99 × 109 m F−1)
4πε0
elementary charge e = 1.60 × 10−19 C

the Planck constant h = 6.63 × 10−34 J s

unified atomic mass unit 1 u = 1.66 × 10−27 kg

rest mass of electron me = 9.11 × 10−31 kg

rest mass of proton mp = 1.67 × 10−27 kg

molar gas constant R = 8.31 J K−1 mol−1

the Avogadro constant NA = 6.02 × 1023 mol−1

the Boltzmann constant k = 1.38 × 10−23 J K−1

gravitational constant G = 6.67 × 10−11 N m2 kg−2

acceleration of free fall g = 9.81 m s−2

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Formulae

1
uniformly accelerated motion s = ut + 2 at 2
v 2 = u 2 + 2as

work done on/by a gas W = p ΔV

Gm
gravitational potential φ = −
r

hydrostatic pressure p = ρgh

1 Nm 2
pressure of an ideal gas p = 〈c 〉
3 V
simple harmonic motion a = − ω 2x

velocity of particle in s.h.m. v = v0 cos ωt

v = ± ω (x 02 - x 2)
fsv
Doppler effect fo =
v ± vs

Q
electric potential V =
4πε0r

capacitors in series 1/C = 1/C1 + 1/C2 + . . .

capacitors in parallel C = C1 + C2 + . . .

1
energy of charged capacitor W = 2 QV

electric current I = Anvq

resistors in series R = R1 + R2 + . . .

resistors in parallel 1/R = 1/R1 + 1/R2 + . . .

BI
Hall voltage VH =
ntq

alternating current/voltage x = x0 sin ω t

radioactive decay x = x0 exp(−λt )

0.693
decay constant λ =
t 1
2

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BLANK PAGE

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Answer all the questions in the spaces provided.

1 (a) (i) Define resistance.

...........................................................................................................................................

.......................................................................................................................................[1]

(ii) A potential difference of 0.60 V is applied across a resistor of resistance 4.0 GΩ.

Calculate the current, in pA, in the resistor.

current = ..................................................... pA [2]

(b) The energy E transferred when charge Q moves through an electrical component is given by
the equation

E = QV

where V is the potential difference across the component.

Use the equation to determine the SI base units of potential difference.

SI base units .......................................................... [3]

[Total: 6]

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2 (a) A resultant force F moves an object of mass m through distance s in a straight line. The
force gives the object an acceleration a so that its speed changes from initial speed u to final
speed v.

(i) State an expression for:

1. the work W done by the force, in terms of a, m and s

W = .......................................................... [1]

2. the distance s, in terms of a, u and v.

s = .......................................................... [1]

(ii) Use your answers in (i) to show that the kinetic energy of the object is given by
1
kinetic energy = × mass × (speed)2.
2
Explain your working.

[2]

(b) A ball of mass 0.040 kg is projected into the air from horizontal ground, as illustrated in
Fig. 2.1.

Y
path of
ball

h
ball,
mass 0.040 kg

X
ground

Fig. 2.1

The ball is launched from a point X with a kinetic energy of 4.5 J. At point Y, the ball has a
speed of 9.5 m s−1. Air resistance is negligible.

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(i) For the movement of the ball from X to Y, draw a solid line on Fig. 2.1 to show:

1. the distance moved (label this line D)

2. the displacement (label this line S).

[2]

(ii) By consideration of energy transfer, determine the height h of point Y above the ground.

h = ...................................................... m [3]

(iii) On Fig. 2.2, sketch the variation of the kinetic energy of the ball with its vertical height
above the ground for the movement of the ball from X to Y.
Numerical values are not required.

kinetic
energy

0
0 h
height

Fig. 2.2
[2]

[Total: 11]

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BLANK PAGE

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3 A cylindrical disc of mass 0.24 kg has a circular cross-sectional area A, as shown in Fig. 3.1.

cross-sectional force X
area A 8.9 N
constant
30° speed 0.60 m s–1
disc, disc
mass 0.24 kg ground

Fig. 3.1 Fig. 3.2

The disc is on horizontal ground, as shown in Fig. 3.2. A force X of magnitude 8.9 N acts on the
disc in a direction of 30° to the horizontal. The disc moves at a constant speed of 0.60 m s−1 along
the ground.

(a) Determine the rate of doing work on the disc by the force X.

rate of doing work = ..................................................... W [2]

(b) The force X and the weight of the disc exert a combined pressure on the ground of 3500 Pa.

Calculate the cross-sectional area A of the disc.

A = .................................................... m2 [3]

(c) Newton’s third law describes how forces exist in pairs. One such pair of forces is the weight of
the disc and another force Y. State:

(i) the direction of force Y

.......................................................................................................................................[1]

(ii) the name of the body on which force Y acts.

.......................................................................................................................................[1]

[Total: 7]

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4 Two vertical metal plates in a vacuum are separated by a distance of 0.12 m.

Fig. 4.1 shows a side view of this arrangement.

0.080 m

X sand
particle

2.0 m

0V + 900 V

path of
particle
metal plate
metal plate
Y

0.12 m

Fig. 4.1 (not to scale)

Each plate has a length of 2.0 m. The potential difference between the plates is 900 V. The electric
field between the plates is uniform.

A negatively charged sand particle is released from rest at point X, which is a horizontal distance
of 0.080 m from the top of the positively charged plate. The particle then travels in a straight line
and collides with the positively charged plate at its lowest point Y, as illustrated in Fig. 4.1.

(a) Describe the pattern of the field lines (lines of force) between the plates.

...................................................................................................................................................

...................................................................................................................................................

...............................................................................................................................................[2]

(b) State the names of the two forces acting on the particle as it moves from X to Y.

...............................................................................................................................................[1]

(c) By considering the vertical motion of the sand particle, show that the time taken for the particle
to move from X to Y is 0.64 s.

[2]

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(d) Calculate the horizontal component of the acceleration of the particle.

horizontal component of acceleration = ................................................ m s−2 [2]

(e) (i) Calculate the magnitude of the electric field strength.

electric field strength = ................................................ N C−1 [2]

(ii) The sand particle has mass m and charge q. Use your answers in (d) and (e)(i) to
q
determine the ratio .
m

ratio = ............................................... C kg−1 [2]

q
(f) Another particle has a smaller magnitude of the ratio than the sand particle. This particle is
also released from point X. m

For the movement of this particle, state the effect, if any, of the decreased magnitude of the
ratio on:

(i) the vertical component of the acceleration

.......................................................................................................................................[1]

(ii) the horizontal component of the acceleration.

.......................................................................................................................................[1]

[Total: 13]

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5 A vertical tube of length 0.60 m is open at both ends, as shown in Fig. 5.1.

tube

N 0.60 m

direction of
incident
sound wave

Fig. 5.1

An incident sinusoidal sound wave of a single frequency travels up the tube. A stationary wave
is then formed in the air column in the tube with antinodes A at both ends and a node N at the
midpoint.

(a) Explain how the stationary wave is formed from the incident sound wave.

...................................................................................................................................................

...................................................................................................................................................

...................................................................................................................................................

...............................................................................................................................................[2]

(b) On Fig. 5.2, sketch a graph to show the variation of the amplitude of the stationary wave with
height h above the bottom of the tube.

amplitude

0
0 0.20 0.40 0.60
h/m

Fig. 5.2
[2]

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(c) For the stationary wave, state:

(i) the direction of the oscillations of an air particle at a height of 0.15 m above the bottom of
the tube

.......................................................................................................................................[1]

(ii) the phase difference between the oscillations of a particle at a height of 0.10 m and a
particle at a height of 0.20 m above the bottom of the tube.

phase difference = ........................................................ ° [1]

(d) The speed of the sound wave is 340 m s−1.

Calculate the frequency of the sound wave.

frequency = .................................................... Hz [2]

(e) The frequency of the sound wave is gradually increased.

Determine the frequency of the wave when a stationary wave is next formed.

frequency = .................................................... Hz [1]

[Total: 9]

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6 (a) Define the ohm.

...............................................................................................................................................[1]

(b) A battery of electromotive force (e.m.f.) E and internal resistance 1.5 Ω is connected to a
network of resistors, as shown in Fig. 6.1.

E 1.5

I
2.0 RZ
1.8 A
Y Z
8.0

0.60 A X

Fig. 6.1

Resistor X has a resistance of 8.0 Ω. Resistor Y has a resistance of 2.0 Ω. Resistor Z has a
resistance of RZ. The current in X is 0.60 A and the current in Y is 1.8 A.

(i) Calculate:

1. the current I in the battery

I = ....................................................... A [1]

2. resistance RZ

RZ = ...................................................... Ω [2]

3. e.m.f. E.

E = ...................................................... V [2]

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(ii) Resistors X and Y are each made of wire. The two wires have the same length and are
made of the same metal.

Determine the ratio:

cross-sectional area of wire X

1.
cross-sectional area of wire Y

ratio = .......................................................... [2]

average drift speed of free electrons in X

2. .
average drift speed of free electrons in Y

ratio = .......................................................... [2]

[Total: 10]

Please turn over for Question 7.

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7 A sample of a radioactive substance may decay by the emission of either α-radiation or β-radiation
and/or γ-radiation.

State the type of radiation, one in each case, that:

(a) consists of leptons

...............................................................................................................................................[1]

(b) contains quarks

...............................................................................................................................................[1]

(c) cannot be deflected by an electric field

...............................................................................................................................................[1]

(d) has a continuous range of energies, rather than discrete values of energy.

...............................................................................................................................................[1]

[Total: 4]

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