How did you go within the 2018 HSC Physics Examination? Learn this put up to test the solutions and explanations to the 2018 HSC Physics Examination Paper.
This paper was damaged into two sections.
Part 1 relies on the core subjects and has 2 components:
- Half A – 20 A number of Alternative Questions
- Half B – 10 Brief Reply Questions
Part 2 relies on possibility subjects and has 5 questions. We have now included the solutions to the preferred possibility subjects:
- Medical Physics
- Astrophysics
- From Quanta to Quarks
Part 1 – 75 Marks
Half A – 20 Marks
Query | Reply | Clarification |
1 |
A | The gravitational drive is in the direction of the centre of the Earth, therefore the acceleration is in the direction of the centre of the Earth |
2 |
B | The graph as proven ought to be depth vs wavelength, and better temperatures emit extra radiation. |
3 |
A | The ISS collides with air molecules within the higher environment (air resistance) and loses momentum. |
4 |
D | The lower in rotation pace decreases the again EMF, which will increase whole EMF and present. |
5 |
B | Pressure is given by ( F = B I L sin theta = 1 occasions 2 occasions 0.08 occasions sin(30) = 0.05 N ) |
6 |
B | The saucepan should be a conductor for currents to be induced. A excessive AC frequency is important for a excessive change in flux and excessive induced present. |
7 |
A | The acceleration on the floor of a planet is proportional to the mass, and the inverse of the sq. of radius; Doubling the mass doubles the acceleration, however doubling the radius decreases the acceleration by an element of 4 – these mix for a brand new ‘g’ that’s ½ of the previous. |
8 |
D | Lattice U is a p-type, because the dopant offers 3 electrons. There’s nonetheless a band hole between the conduction and valence band, which means the corresponding diagram is X. (Be aware: Lattice T is an n-type semiconductor, and band diagram Y corresponds to a steel.) |
9 |
A | A decreased distance to journey will yield a decreased journey time, therefore the astronaut can survive the journey. |
10 |
C | The route of torque should be fixed – in any other case the motor won’t work. Therefore the route of drive on component WX should reverse each 180 levels. |
11 |
D | An elevated g drive is because of an upward acceleration of the thing containing an individual; case D is the one instance the place this happens. |
12 |
A | The electrons will expertise an upward drive in the direction of the constructive plate.
Utilizing the appropriate hand rule (or the left hand rule for an electron), the magnetic area should be into the web page to offer a balancing drive downwards. The magnitude might be calculated by equating $$qE = qvB$$ $$B = frac{E}{v} = 0.5 T$$ |
13 |
B | The drive on the electron will improve, as F = qvB.
This drive is the centripetal drive of round movement; by equation ( qvB = frac{mv^{2}}{r}), we will conclude that v is proportional to r. Therefore the radius will improve. |
14 |
C | The connection between L and T is (L = frac{gT^{2}}{(4pi^{2})} ), so solely C or D present this sq. relationship.
As g is bigger on Earth, a given interval might be achieved with an extended size in comparison with Mars, therefore the graph for Earth might be above that of Mars. |
15 |
D | Michelson tried to display a distinction in journey occasions for arms parallels / perpendicular to the route of earth’s journey because of aether wind. |
16 |
A | A shifting observer will see size contraction for all different objects; therefore they’ll see the tunnel contract. As a consequence of relativity of simultaneity, they’ll see picture 2 being taken earlier than picture 1, as they’re travelling in the direction of the situation of the photo-2 occasion. |
17 |
C | The graph exhibits the work perform for zinc is the best; therefore any photon energetic sufficient to extract electrons from zinc can even extract electrons from potassium. |
18 |
B | The induced present will oppose any change in flux. Through proper hand grip rule, the decrease solenoid will generate a downward B area. The solenoid above will thus generate an upward B area to counter this modification; these two fields will repel each other and the pointer will transfer up. The route of present might be discovered once more from proper hand grip rule. |
19 |
B | An observer contained in the bus will see the the ball transfer in the direction of the entrance of the bus. From the angle of a passenger, the ball has each a ahead (because of the (3 m/s^{2}) slowdown of the bus) and downward acceleration; this can end in a linear movement! The preliminary velocity of the ball from the angle of the passenger is zero. |
20 |
C | The needle in X might be pressured leftward to oppose the change in flux from the rotating galvanometer. Therefore, the generated present should be such that the needle strikes to the left; this can be a detrimental present. Tracing the wires from X to Y exhibits {that a} detrimental present coming from X can even yield a detrimental present by Y, and therefore the needle will transfer to the left. |
Half B – 55 Marks
Query 21 ( 4 Marks)
(a) | The 2 forces are equal and reverse, in keeping with Newton’s third Regulation |
(b) | Mass on Earth and Moon is 70 kg.
Weight on Earth is w = mg = 70 x 9.8 = 686 N Weight on the Moon is w = mg = 70 x 1.6 = 112 N |
Query 22 (6 marks)
(a) | The movement of the magnet will end in areas of the disc experiencing a change in magnetic flux because the poles of the magnet transfer throughout them.
This can end in an induced EMF (Faraday’s Regulation) within the disc and eddy currents. The eddy currents will produce a magnetic area to oppose the change within the flux (Lenz’s Regulation) which can end in a drive and a torque on the disc. The disc will rotate in the identical route because the magnet |
(b) | Graph wants to indicate a sinusoid with interval reducing and amplitude rising over the primary three seconds |
Query 23 (5 marks)
(a) | The electrons take in thermal power (warmth) from the heating filament and escape the steel. The electrical area within the electron gun does work on the electrons and will increase their kinetic power. After they strike the display they cease and their kinetic power is transferred to the phosphor within the display, which converts it to warmth and lightweight. |
(b) | Y are solenoids (electromagnets) which produce magnetic fields. The magnetic fields are used to deflect the electron beam and scan it throughout the display. There should be two pairs of such coils, one for controlling horizontal deflection and one for controlling vertical deflection.
The picture is shaped by raster scanning, i.e. by scanning the beam throughout the display from pixel to pixel and altering the ability of the beam (e.g. the no. of electrons) because the beam hits every pixel to alter the depth of that pixel. As soon as a picture is shaped, the scanning repeats to refresh the picture |
Query 24 (5 marks)
(a) | The excessive voltage wires are hooked up to the supporting constructions utilizing insulators with a view to electrically isolate them from the bottom. Lightning safety is used: wires positioned above the transmission traces, and the supporting towers are steel, nicely earthed and separated from one another. Present from lightning strikes can safely be performed to the bottom |
(b) | Wires will appeal to one another if the present is in the identical route.
To ensure that there to be zero internet drive on Y, it should be drawn to X by the identical energy as it’s drawn to Z, therefore the present in X is to the appropriate. $$F = frac{kI_{1}I_{2}L}{d}$$ $$frac{kI_{X}I_{Y}L}{d_{XY}} =frac{kI_{Y}I_{Z}L}{d_{YZ}} $$ $$frac{I_{X}}{0.75} =frac{20}{320} $$ $$I_{X} = 50 A$$ |
Query 25 (6 marks)
(a) Profit: No energy loss because of heating as resistance is zero. Limitation: Should be stored beneath their important temperature with a view to be superconducting (have zero resistance), which is troublesome and consumes power.
(b) The desk compares the steel and superconductors.
Cooper pairs expertise no resistance. Via their interplay with the lattice one electron loses one phonon of power and the second electron absorbs one phonon. Therefore there isn’t any internet power loss for the Cooper pair.
Metallic at room temperature | Superconducting steel beneath important temperature | |
Conduction by | Single electrons | Pairs of electrons (Cooper pairs) |
Mechanism | Electrons within the conduction band are cell and may transfer by the steel. | At low temperatures lattice vibrations scale back. An electron will appeal to close by constructive ions inflicting lattice distortion and can lose one phonon of power. The lattice distortion will improve constructive cost density which attracts a second electron that absorbs one phonon of power. These two electrons are paired by the lattice and kind the Cooper pair. |
Resistance | Electrons expertise resistance.
As electrons transfer by the lattice they collide with constructive ions. These collisions are inelastic on common and the electrons lose power to the lattice (transformed to warmth). |
Cooper pairs expertise no resistance.
Via their interplay with the lattice one electron loses one phonon of power and the second electron absorbs one phonon. Therefore there isn’t any internet power loss for the Cooper pair. |
Query 26 (4 marks)
Gravitational Discipline | Electrical Discipline | |
Acts on | Mass | Cost |
Pressure it mediates | Gravitational drive of attraction | Electrical Pressure |
Definition and models | Pressure per unit mass: N/kg
$$g = frac{F_{G}}{m}$$ Path is the route of drive on a mass |
Pressure per unit cost: N/C
$$E = frac{F_{E}}{q}$$ Path is the route of drive on a constructive cost |
Acceleration of object | All lots in a relentless area will speed up with the identical acceleration and within the route of the sphere | All costs in a relentless area will expertise an acceleration that is dependent upon their charge-to-mass ratio (q/m). Constructive costs speed up within the route of the sphere and detrimental costs in the other way. |
Trajectory in a uniform area | Parabolic trajectory (projectile movement)
Pressure and acceleration are fixed in magnitude and route. Part of velocity perpendicular to the sphere stays fixed. Particle accelerates in route of drive. |
Query 27 (6 marks)
(a) | The digital camera is viewing the projectile and the ruler at an angle leading to a parallax error. This can end in a scientific error within the horizontal place of the particle |
(b) | The horizontal velocity stays fixed, the horizontal acceleration is zero. The gradient of the graph offers the speed:
$$v_{x} = -1.6 m/s $$ The vertical acceleration is fixed so the vertical velocity adjustments at a relentless fee. The preliminary velocity is 4.2 m/s, the ultimate velocity is -4.8 m/s. The gradient of the graph offers the acceleration: ( a_{y} = -9.5 m/s^{2} ) |
Query 28 ( marks)
(a) | $$Delta Ep = Ep_{f} – Ep_{i}$$
$$= frac{-GMm}{r_{f}} – frac{-GMM}{r_{i}}$$ $$= -GMm [frac {1}{r_{f}} – frac{1}{r_{i}}]$$ $$= -6.67 occasions 10^{-11} occasions 7.35 occasions 10^{22} occasions 20 [frac{1}{1740 000+500 000} – frac{1}{1740000}]$$ $$= 1.257… occasions 10^{7} J$$ $$= 1.26 occasions 10^{7} J$$ |
(b) | If the potential power will increase by ( 1.26 occasions 10^{7} J ), the kinetic power should lower by the identical quantity to preserve power.
( KE_{Preliminary} = frac{1}{2} mv^{2} = frac{1}{2} occasions 20 occasions 1200^{2} = 1.44 occasions 10^{7} J ) (KE_{Closing} = 1.44 occasions 10^{7} – 1.26 occasions 10^{7} = 1.8 occasions 10^{6} J ) (frac{1}{2} mv^{2} = 1.8 occasions 10^{6} J ) (v = 424 m/s) |
Query 29 (8 marks)
(a) | Vacuum photocell:
Photo voltaic Cells:
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(b) | Advance in understanding: understanding of band construction in semiconductors
Our understanding of the valence-conduction band interplay, and significantly the band hole has enabled the event of semiconductor know-how. Particularly, the connection between the power of the band hole and the wavelength of emitted or absorbed photons have prompted using semiconductors in mild technology (LEDs) and power technology from mild (Photo voltaic Panels). For these innovations to be applied, nevertheless an advance in know-how was required: purification of semiconductors and doping to regulate the band hole of semiconductors. With the power to engineer a exact, managed band-gap mild emitters and absorbers working at particular wavelengths might be generated, resulting in the wide range of colored LEDs and the excessive effectivity of photo voltaic panels, leading to a considerably elevated utilization of semiconductors. |
Query 30 (6 marks)
A rise within the variety of electrical home equipment being utilized in homes means the homes will draw use extra power. This can require them to attract extra energy (P = E/t) and extra present from the secondary coil of step-down transformer T2 (P= VI, and V = 240 V = fixed).
The step-down transformer T2 is fastened, so if extra energy is being drawn from its secondary coil, extra energy should be equipped to its main coil within the type of a rise in present. The enter voltage should stay fastened because the output voltage is fixed at 240 V.
Comparable, extra present might be drawn from step-up transformer T1, and therefore extra present should be equipped to it.
Results on
- Generator/energy station: Rotates on the similar pace to maintain voltage and frequency fastened. Would require extra torque (mechanics power enter) with a view to produce extra present and therefore extra energy or power.
- Transformers: Voltages stay fixed however currents improve. The upper present Will increase the warmth produced (Joule warmth losses) which suggests a number of the power is transformed to warmth and the transformers’ effectivity reduces.
- Energy traces: The elevated present will improve the warmth produced which means the some electrical power is transformed to warmth. This additionally leads to a voltage drop throughout the ability line relying on the present and resistance of the ability line (V = IR).
2. Part 2 – 25 marks
Query 32 – Medical Physics (25 marks)
(a) | (i) MRI is appropriate to be used in analyzing smooth tissue with excessive water content material. It’s helpful for finding tumors and smooth tissue illness, and to diagnose A number of Sclerosis (MS).
(ii) The appliance of a powerful magnetic area adjustments the spin orientation of hydrogen nuclei within the physique. From an preliminary random state, the nuclei align both parallel or anti-parallel. A slight majority of nuclei are parallel – this constitutes the decrease power configuration. |
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(b) | (i) At a boundary between tissues the place there’s an acoustic impedance mismatch, a fraction of the ultrasound wave might be mirrored, and the rest of the wave might be transmitted.
As a result of differing impedances of the 2 supplies, each waves B and A will expertise some reflection on the fat-kidney interface. The reflection coefficient is a product completely of the variations and sums of the impedances, no matter which is the incident and transmissive medium – there ought to be no distinction between the transmission of wave A and wave B. (ii) Impedance of kidney tissue, ( Z = rho occasions v = 1050 occasions 1560 = 1.638 occasions 10^{6}rayls) $$R=frac{(Z_{kidney} – Z_{fats})^{2}}{(Z_{kidney} + Z_{fats})^{2}}$$ Substitute R = 0.01 $$0.01=frac{(Z_{kidney} – Z_{fats})^{2}}{(Z_{kidney} + Z_{fats})^{2}}$$ $$0.1=frac{Z_{kidney} – Z_{fats}}{Z_{kidney} + Z_{fats}}$$ $$0.1(Z_{kidney} + Z_{fats})=Z_{kidney} – Z_{fats}$$ $$0.9Z_{kidney}=1.1Z_{fats}$$ Substitute ( _{kidney} = 1.638 occasions 10^{6} rayls) ( Z_{fats} = 1.340 occasions 10^{6} rayls ) |
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(c) | Standards for suitability in analysis; emission kind, half life and chemical compatibility (toxicity).
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(d) | The change in frequency brought on by the relative movement between a sound supply and an observer is named the Doppler Impact.
The Doppler impact is used in Doppler sonography and ultrasonography. Acoustic waves reflecting off a shifting goal will expertise a change in frequency proportional to the speed and route of the goal. Therefore this permits the stream of fluids within the goal to be measured. Particular functions embrace:
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(e) |
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Query 33 – Astrophysics (25 marks)
(a) | (i) One parsec is the space to an arc or chord that subtends an angle of parallax of 1 arc second.
(ii) Trigonometric parallax measurements are restricted by the decision of the telescope: (Delta theta = frac{1.22 lambda}{D}) The place D is the aperture diameter, (lambda) is the noticed wavelength and (Delta theta) is the dimensions of the Ethereal disc. A parallax might be noticed if the shift in obvious place might be resolved in keeping with Rayleigh’s criterion. Atmospheric transparency is sweet for less than radio and optical wavelengths. Shorter wavelengths (UV) are blocked by the environment so the smaller parallaxes measurable can solely be noticed from area. Floor-based optical telescopes at any altitude additionally cope with atmospheric turbulence that distorts incoming wavefronts and blurs the picture. This decreases efficient decision therefore limiting parallax measurements making decision worse than the above equation for (Delta theta.) |
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(b) | (i)
(ii) From graph B: (T = 7 – 1 = 6) days $$M = m – 5 log (frac{d}{10})$$ |
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(c) | Star X begins as predominant sequence blue big B-class star with core hydrogen fusion continuing through the CNO cycle. When ample helium is deposited into the core, hydrogen fusion continues in a shell across the core and helium core fusion begins.
Elevated radiation stress expands the outer layers inflicting cooling and the star is now a crimson supergiant. Carbon from the helium fusion can fuse within the core whereas hydrogen and helium fuse in surrounding shells (outer shells with lighter parts). The core area is like shells of an onion. Oxygen fusion ought to happen yielding a bigger, redder, crimson supergiant. The star ends life as a supernova explosion (creating many different parts) whereas the core of oxygen, neon and different parts collapses right into a neutron star. Be aware: A flowchart may additionally be ample so long as it didn’t compromise on element. |
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(d) | Photoelectric applied sciences (e.g. CCD cameras) have improved measurements in astrometry, photometry and particularly spectroscopy.
Greater spatial decision over photographic plates yields higher parallax and distance measurements. Greater accuracy and reliability in photometry yields improved understanding of how color pertains to different properties of stars (luminosity and so on) with wider frequency protection. Spectroscopy sees the best advantages. Photographic spectra are 2D photographs the place relative spectral line intensities can’t be decided quantitatively precisely. Photoelectric detectors usually are not simply extra delicate to a wider vary of wavelengths (therefore yielding extra chemical info from different spectral traces) however permit 1D spectra to be produced simply the place spectral line intensities might be quantified exactly. This improves calculations of redshift (or blueshift) for radial velocities and line broadening because of Doppler broadening (thermal and rotational) and stress broadening. Throughout the board, moreover, CCDs yield sooner knowledge assortment, decreased knowledge loss and improved knowledge comparability. |
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(e) | Emission Spectra:
Stellar emission spectra are noticed by trying on the environment of the star in opposition to the backdrop of area. Meaning observing sizzling fuel in opposition to a colder background. The ensuing spectrum exhibits emission traces of assorted species (chemical composition) and which traces of which species are seen signifies the temperature of the stellar environment. In a faculty lab, one can observe a fuel lamp (e.g hydrogen or mercury) or fluorescent mild tubes by a spectroscope in a darkened room.
Blackbody Spectra: These are produced by blackbody radiators similar to stellar cores. Since such objects are by no means with no surrounding environment, they aren’t seen straight however because the underlying envelope of stellar absorption spectra. Blackbody spectra alone yield no chemical info (is a easy spectrum by definition) they point out precisely the floor temperature of the star from the distinctive peak wavelength of the spectrum, the place ( lambda_{peak}) is proportional to (frac{1}{temperature}). This implies larger temperature yields shorter peak wavelength (hotter, bluer stars). In a faculty lab, one might observe the glowing tungsten filament of an incandescent mild bulb by a spectroscope in a darkened room.
Absorption Spectra: These are produced by observing comparatively cooler fuel in opposition to a brighter and warmer background. Therefore stellar absorption spectra are obtained by observing a star straight. The result’s a blackbody spectrum (from the inside stellar core) superimposed with darkish traces or dips. The height of the blackbody yields temperature whereas the absorption traces yield chemical composition since all atoms are ions have distinctive attribute wavelengths of absorption (and emission). Which line of which species additionally signifies temperature. In a faculty lab, one can observe a white mild by a clear field of fuel (e.g. hydrogen, oxygen, air) or by dispersing a pattern in a flame and observing the flame with a vibrant backlight utilizing a spectroscope in a darkened room (e.g. AAS in Chemistry).
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Query 34 – From Quanta to Quarks (25 marks)
(a) | (i) Bohr’s mannequin couldn’t predict atomic spectra for atoms containing a couple of electron. It didn’t clarify the mechanisms of secure orbits. It couldn’t clarify the Zeeman impact or hyper high quality splitting of spectral traces.
(ii) Bohr’s mannequin proposes that electrons exist in particular, secure orbitals across the nucleus. These orbitals have a particular power. Electrons at a excessive power orbital could decay to a decrease power orbital by emitting a photon of sunshine with an power equal to the distinction of the 2 orbitals; as a result of all of those orbitals are discrete, particular ranges, there are just a few photon energies (therefore wavelengths) that might be emitted. |
(b) | (i) Chadwick used the legal guidelines of conservation of momentum and power to determine the mass of particle X. He measured the ultimate momenta and power of the ejected protons, and used these conservation legal guidelines to deduce the mass of the particle X.
(ii) Mass of Reactants: 4.0012+9.0122 = 13.0134 amu. Mass of Merchandise: 12 + 1.0087 = 13.0087 amu. Mass defect = Mass of Reactants – Mass of Merchandise = 0.0047 amu. Convert to kg by multiplying by (1.661 occasions 10^{-27} = 7.8067 occasions 10^{-30} kg. ) Convert to joules through (E = mc^{2} = 7.0260 times10^{-13} J ) |
(c) | Graph of kinetic energies of beta particles after a particular beta decay response. Graph ought to be a distribution displaying a steady vary of various energies are doable – this contrasts to the ‘anticipated’ kinetic power, which ought to be a single worth – this anticipated worth ought to be proven on the graph, on the highest power level.
Pauli’s proposal of the neutrino was an answer to the power distribution of beta particles in beta decay – for a given decay the overall power launched was fixed, and it was anticipated that the kinetic power of the launched beta particle could be fixed – as it’s by far the lighter of the 2 merchandise, it ought to obtain the entire launched power. This was not discovered to be the case – the power of beta particles different considerably – suggesting a violation of conservation of power. Pauli instructed an unobserved particle could also be accountable, carrying some power away from the response with out being detected – the neutrino. Because it was undetected till this stage, it should have no cost, low mass and minimal interactions with different particles |
(d) | From the diagrams, we will see that the decay merchandise of
Every nucleus of supply X present process alpha decay would lose 4 nucleons whole; 2 neutrons and a pair of protons. Supply Y is present process beta decay, most probably beta-minus (as positron decay would produce brief tracks because of the positron annihilating itself with an electron). In every nucleus of Y present process this decay, one neutron is transformed right into a proton, with an electron (beta-minus particle) being emitted together with an anti-neutrino. |
(e) | The usual mannequin describes what matter is manufactured from and the way it interacts. Based on the usual mannequin matter is made up of quarks and leptons, and interacts by elementary forces by exchanging drive provider particles.
There are six quarks (u, d, c, s, t, b) and 6 leptons (e, mu, tau, and three neutrinos), in addition to their antimatter counterparts. The elemental forces are the sturdy drive (mediated by gluons) that acts on quarks and gluons, the weak drive (mediated by W and Z bosons) that acts on quarks and leptons, and the electromagnetic drive that acts on charged particles (mediated by photons). (The usual mannequin doesn’t clarify gravity.) Out present understanding of the atom is that it’s composed of a nucleus consisting of positively charged protons and impartial neutrons, surrounded by negatively charged electrons in discrete power ranges. The electrons work together with the nucleus by the electromagnetic drive mediated by photons. The electrons are drawn to the nucleus by this drive which binds them to it. Within the nucleus, the protons and neutrons (nucleons) are examples of hadrons – composite particles manufactured from three quarks (uud for protons, and udd for neutrons). The quarks in every hadron are held collectively by the sturdy drive, mediated by gluons. The nucleons are held collectively by the (residual) sturdy drive which is engaging on the typical separation between nucleons. In a secure nucleus, the (residual) sturdy drive overcomes the electrostatic repulsion between the protons (because of their constructive cost) and is ready to bind each protons and neutrons to the nucleus. The neutrons are required as they improve the attraction because of the sturdy drive with out rising repulsion because of the electrical drive, and therefore they contribute to the steadiness of the nucleus. |
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