1 hour 15 minutes
N15/4/PHYSI/SP2/ENG/TZ0/XX
Physics
Standard level Paper 2
Instructions to candidates ? Write your session number in the boxes above.
? Do not open this examination paper until instructed to do so.? Section A: answer all questions.? Section B: answer one question.
? Write your answers in the boxes provided.? A calculator is required for this paper.
? A clean copy of the physics data booklet is required for this paper.?
The maximum mark for this examination paper is [50 marks]
.
20 pages
? International Baccalaureate Organization 2015
Monday 9 November 2015 (morning)
Candidate session number
8815 – 6505
(Question 1 continued)
(b) State why the line of best-fit suggests that h
is not proportional to T.[1]
mean
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(c) (i) State the uncertainty in each value of T.[1]
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(ii) The temperature is measured using a liquid in glass thermometer. State what
physical characteristic of the thermometer suggests that the change in the liquid’s
length is proportional to the change in temperature.[1]
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=?KT 3 where K is a constant. Using the graph on
(d) Another hypothesis is that h
mean
page 2, calculate the absolute uncertainty in K corresponding to T?=?50 °C.[4]
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2. This question is about gravitation and uniform circular motion.
Phobos, a moon of Mars, has an orbital period of 7.7 hours and an orbital radius of 9.4 ×103 km.
(a) Outline why Phobos moves with uniform circular motion.[3]
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(b) Show that the orbital speed of Phobos is about 2 km s–1.[2]
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(c) Deduce the mass of Mars.[3]
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(Question 3 continued) (c)
Determine the maximum displacement of X. Give your answer to an appropriate number of significant figures.
[4]
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(d)
A second object Y oscillates with the same frequency as X but with a phase difference of 4
π
. Sketch, using the graph opposite, how the acceleration of object Y varies with t .[2]
4.
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(Question 4, part 1 continued) (c)
The nuclide radium-226 88226Ra ()
decays into an isotope of radon (Rn) by the emission of an alpha particle and a gamma-ray photon.
(i)
State what is meant by the terms nuclide and isotope.
[2]
N uclide: .................................................................
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I sotope: .................................................................
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(ii) Construct the nuclear equation for the decay of radium-226.[3]
88226
Ra
Rn He ........................................
....→
++................
γ
(iii) Radium-226 has a half-life of 1600 years. Determine the time, in years, it takes
for the activity of radium-226 to fall to 1
64
of its original activity.
[2]
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(Question 4, part 2 continued)
(e) (i) Wave A has a frequency of 9.0 Hz. Calculate the velocity of wave A.[2]
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(ii) Deduce the frequency of wave B.[3]
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(f) (i) State what is meant by the principle of superposition of waves.[2]
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(ii) On the graph opposite, sketch the wave that results from the superposition of
wave A and wave B at that instant.[3]
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5.
(c) Fission of one uranium-235 nucleus releases 203 MeV.
(i) Determine the maximum amount of energy, in joule, released by 1.0 g of
uranium-235 as a result of fission.[3]
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(ii) Coal has an energy density of 2.8 ×107 J kg–1.
Calculate the ratio energy density of uranium-235
energy density of coal
.[1]
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(iii) Using your answer to (c)(ii), outline why fossil fuel stations are often built near
to the source of the fossil fuel but nuclear power stations are rarely close to the
source of the nuclear fuel.[2]
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(f) A mass of 0.22 kg of lead spheres is placed in a well-insulated tube. The tube is
turned upside down several times so that the spheres fall through an average height of 0.45 m each time the tube is turned. The temperature of the spheres is found to increase by 8 °
C.
(i) Discuss the changes to the energy of the lead spheres.[2]
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(ii) The specific heat capacity of lead is 1.3×102 J kg–1 K–1. Deduce the number of times that the tube is turned upside down.[4]
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(a)
(Question 6, part 1 continued)
(b) B slows down while I remains at a constant speed. The driver in each car wears
a seat belt. Using Newton’s laws of motion, explain the difference in the tension in the
seat belts of the two cars.[3]
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(c) A third car O with mass 930 kg joins the race. O collides with I from behind, moving
along the same straight line as I. Before the collision the speed of I is 45 m s–1 and its
mass is 850 kg. After the collision, I and O stick together and move in a straight line
with an initial combined speed of 52 m s–1.
(i) Calculate the speed of O immediately before the collision.[2]
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(ii) The duration of the collision is 0.45 s. Determine the average force acting on O.[2]
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(Question 6 continued)
Part 2Electrical circuits
The circuit shown is used to investigate how the power developed by a cell varies when the load resistance R
changes.
The variable resistor is adjusted and a series of current and voltage readings are taken.
The graph shows the variation with R of the power dissipated in the cell and the power
dissipated in the variable resistor.
P / W 1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
power dissipated in resistor
power dissipated in cell
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5
R / Ω
(This question continues on the following page)
(d) An ammeter and a voltmeter are used to investigate the characteristics of a variable
resistor of resistance R. State how the resistance of the ammeter and of the voltmeter
compare to R so that the readings of the instruments are reliable.[2]
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(e) Show that the current in the circuit is approximately 0.70 A when R =?0.80 Ω.[3]
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(f) The cell has an internal resistance.
(i) Outline what is meant by the internal resistance of a cell.[2]
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(ii) Determine the internal resistance of the cell.[3]
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