This report is a re-evaluation on DMF as derived in conventional books and as we have used to derive. The report shows in details about the changes in values obtained.
This report is a re-evaluation on DMF as derived in conventional books and as we have used to derive. The report shows in details about the changes in values obtained.
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Session Overview
-------------------------------------------
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State of global ICS asset and network exposure
Sectoral targets and attacks as well as the cost of ransom
Global APT activity, AI usage, actor and tactic profiles, and implications
Rise in volumes of AI-powered cyberattacks
Major cyber events in 2024
Malware and malicious payload trends
Cyberattack types and targets
Vulnerability exploit attempts on CVEs
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Cyber risk predictions
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I have heard many times that architecture is not important for the front-end. Also, many times I have seen how developers implement features on the front-end just following the standard rules for a framework and think that this is enough to successfully launch the project, and then the project fails. How to prevent this and what approach to choose? I have launched dozens of complex projects and during the talk we will analyze which approaches have worked for me and which have not.
"Impact of front-end architecture on development cost", Viktor Turskyi
Nature of light a
1. 1. (a) Calculation of energy required by atom (1)
Answer [1.8 (eV)] (1)
Example of answer:
Energy gained by atom = 13.6 eV – 3.4 eV = 10.2 eV
KE of electron after collision = 12 eV – 10.2 eV = 1.8 eV 2
(b) Use of E = hf and c = fλ (1)
Conversion of eV to Joules (1)
–7
Answer = [1.22 × 10 m] (1)
Example of answer
E = hf and c = fλ E = hc/λ
λ = (6.63 × 10–34 J s × 3 × 108 m s–2) ÷ (10.2 eV × 1.6× 10–19 C)
–7
λ = 1.21 × 10 m 3
[5]
2. (a) Diffraction is the change in direction of wave or shape or
wavefront (1)
when the wave passes an obstacle or gap (1) 2
(b) The energy of the wave is concentrated into a photon (1)
One photon gives all its energy to one electron (1) 2
(c) Energy of photon increases as frequency increases OR reference to
E = hf (1)
Electrons require a certain amount of energy to break free and this
corresponds to a minimum frequency (1) 2
[6]
3. (a) Meaning of statement
–19
(5.89 × 10 J / work function) is the energy needed to remove an
electron [allow electrons] from the (magnesium) surface/plate
Consequent mark
Minimum energy stated or indicated in some way [e.g. at least /or more] (1) 2
2. (b) (i) Calculation of time
Use of P = IA (1)
Use of E = Pt (1)
[use of E = IAt scores both marks]
Correct answer [210 (s), 2 sig fig minimum, no u.e.] (1)
[Reverse argument for calculation leading to either intensity,
energy or area gets maximum 2 marks]
Example calculation:
–19 –2 –20 2
t = (5.89 × 10 J)/(0.035 W m × 8 × 10 m ) 3
(ii) How wave-particle duality explains immediate photoemission
QOWC (1)
Photon energy is hf / depends on frequency / depends on wavelength (1)
One/Each photon ejects one/an electron (1)
The (photo)electron is ejected at once/immediately (1)
[not just ‘photoemission is immediate’] 4
[9]
4. (a) Blue light:
Wavelength / frequency / (photon) energy 1
(b) (i) Frequency:
Conversion of either value of eV to Joules
Use of f = E / h
14 14
Correct frequency range [4.8 × 10 – 8.2 × 10 Hz or range =
14
3.4 × 10 Hz]
[no penalty for rounding errors]
eg.
2 eV = 2 × 1.6x 10–19 = 3.2 × 10–19 J
–34
= 6.63 × 10 × f
14
f = 4.8 × 10 Hz
–19 –19
3.4 eV = 3.4 × 1.6 × 10 = 5.4 × 10 J
14
f = 8.2 × 10 Hz 3
(ii) Diagrams:
Downward arrow from top to bottom level
On larger energy gap diagram 2
3. (c) (i) Resistivity drop:
Less heating / less energy lost / greater efficiency / lower
voltage needed / less power lost 1
(ii) Resistance:
Recall of R = ρL/A
Use of R = ρL/A
Correct answer [80(Ω)] [allow 80–84 (Ω) for rounding errors]
Eg.
–2 –3 –3 –4
R = (2 × 10 × 5.0 × 10 ) / (3.0 × 10 × 4.0 × 10 )
= 83 Ω 3
[10]
5. (a) Part of spectrum
Light / Visible / red (1) 1
Calculation of work function
Use of ϕ = hc/λ (1)
–19
3.06 × 10 [2 sig fig minimum] (1) 2
–34 8 –1 –7
(6.63 × 10 J s)(3.00 × 10 m s )/(6.5 × 10 m)
–19
= 3.06 × 10 J
(b) (i) Meaning of stopping potential
Minimum potential difference between C and A / across the
photocell (1)
Which reduces current to zero OR stops electrons reaching A /
crossing the gap / crossing photocell (1) 2
(ii) Why the graphs are parallel
Correct rearrangement giving Vs = hf/e – ϕ/e (1)
Gradient is h/e which is constant / same for each metal (1)
[Second mark can be awarded without the first if no
rearrangement is given, or if rearranged formula is wrong but
does represent a linear graph with gradient h/e] 2
[7]
4. 6. (a) (i) Table
λ f
2.4 (110)
1.2 220
0.8 330
All wavelengths correct (2)
[One or two wavelengths correct gets 1]
Both frequencies correct (1)
[Accept extra zero following wavelength figure, e.g. 2.40.
Accept units written into table, e.g. “2.4 m”, “220 Hz”] 3
(ii) Why nodes
String cannot move / no displacement / zero amplitude /
no oscillation / phase change of π on reflection / two waves
cancel out / two waves are exactly out of phase (1)
(OR have phase difference of π OR half a cycle) /
destructive interference 1
(b) Why waves with more nodes represent higher energies
More nodes means shorter wavelength (1)
Momentum will be larger (1)
[OR Allow 1 mark for “More nodes means higher frequency and E = hf”] 2
[6]
7. (a) Why statement correct
Blue photon has more energy than red photon (1)
Why statement incorrect
Blue beam carries less energy per unit area per second / Blue beam
carries less energy per second / Blue beam carries less energy per
unit area / Blue beam has lower intensity and intensity = energy per unit
area per second
Additional explanation
[Under “correct”] Blue has a higher frequency (OR shorter wavelength) /
[Under “incorrect”] Blue beam has fewer photons (1)
[Allow reverse statements about Red throughout part a] 3
5. (b) (i) Meaning of work function
Energy to remove an electron from the surface (OR
metal OR substance) (1)
[Don’t accept “from the atom”. Don’t accept “electrons”.]
Minimum energy… / Least energy… / Energy to just…
/ …without giving the electron any kinetic energy (1) 2
(ii) Calculation of threshold frequency
Use of φ = hf0 (1)
14
Correct answer [6.00 × 10 Hz] (1)
e.g.
–19 –34 14
(3.98 × 10 J)/(6.63 × 10 J s) = 6.00 × 10 Hz 2
[7]
8. (a) Which transition
Use of (∆)E = hc/λ OR (∆)E = hf and f = c/λ (1)
–19
Use of 1.6 × 10 (1)
Correct answer [1.9 eV] (1)
C to B / –1.5 to – 3.4 (1)
[Accept reverse calculations to find wavelengths]
e.g.
–34 8 –1
(6.63 × 10 J s)(3.00 × 10 m s )/
–9 –19 –1
(656 × 10 m)(1.6 × 10 J eV )
= 1.9 eV 4
(b) Explanation of absorption line
QOWC (1)
Light of this wavelength is absorbed by hydrogen (1)
In the outer part of the Sun (OR Sun’s atmosphere) (1)
Absorbed radiation is reemitted in all directions (1)
Transition from B to C (OR –3.4 to –1.5) (1) Max 4
(c) Why galaxy receding
Wavelength increased (OR stretched) / red shift /
frequency decreased 1
[9]
6. 9. (a) Work function:
Energy needed for an electron to escape the surface /
to be released (from the metal) (1) 1
(b) How current produced:
Any 3 from:
Photon of light passes energy to an electron
If energy above the work function/frequency above threshold (1)(1)
Electron released as a photoelectron / photoelectron released /
surface electron released (1)
Moving electrons produce a current 3
(c) (i) Intensity of light increased:
More electrons released (1)
(ii) Frequency of light increased:
Electrons gain more (kinetic) energy (1) 2
(d) Photon energy:
Use of f = v/λ or E = hc/λ (1)
–19
Correct answer for E (4.7 × 10 J or 2.96 eV) (1)
[allow 3.0 eV] 2
Example:
8 –7 14
f = v/λ = 3 × 10 / 4.2 × 10 = 7.1 × 10 Hz
–19
E = hf = 4.7 × 10 J or 2.96 eV
OR
8 –34 –7
E = hc/λ = 3 × 10 × 6.63 × 10 / 4.2 × 10
–19
= 4.7 × 10 J or 2.96 eV
(e) Max kinetic energy:
Knowledge that kemax = energy calculated in (d) – φ (1)
–20
Correct answer for kemax (0.26 eV or 4.2 × 10 J)
–20
[allow 0.25–0.26 eV or 4.1 – 4.2 × 10 J and allow ecf from (d)] (1) 2
Example:
kemax = 2.96 eV – 2.7 eV
= 0.26 eV
(f) (i) Why current reduced:
Many / some electrons will not have enough (kinetic) energy
to reach the anode / only electrons with large (kinetic) energy
will reach the anode (1) 1
7. (ii) Stopping potential:
eV = (–) ke
V = ke / e = 0.26V (1) 1
[12]
10. (a) [Treat parts (i) and (ii) together. Look for any FIVE of the
following points. Each point may appear and be credited in either
part (i) or part (ii)]
(i) • Light (OR radiation OR photons) releases electrons from cathode
• Photon energy is greater than work function / frequency of
light > threshold frequency / flight > fo / wavelength of light is
shorter than threshold wavelength / λ < λ0
• PD slows down the electrons (OR opposes their motion OR
creates a potential barrier OR means they need energy to cross
the gap)
• Electrons have a range of energies / With the PD, fewer (OR
not all) have enough (kinetic) energy (OR are fast enough) to
cross gap
• Fewer electrons reach anode / cross the gap
(ii) • (At or above Vs) no electrons reach the anode / cross the gap
• Electrons have a maximum kinetic energy / no electrons have
enough energy (OR are fast enough) to cross
ANY FIVE (1)(1)(1)(1)(1)
[Don’t worry about whether the candidate is describing the effect of
increasing the reverse p.d. (as the question actually asks), or simply
the effect of having a reverse p.d.] 5
(b) Effects on the stopping potential
(i) No change (1)
(ii) Increases (1) 2
[Ignore incorrect reasons accompanying correct statements of the effect]
[7]
11. (a) Explain how vapour emits light
electrons excited to higher energy levels (1)
as they fall they emit photons/electromagnetic radiation/waves/energy (1) 2
8. (b) (i) Meaning of spectral line
(when the light is split up) each frequency/wavelength/photon energy is
seen as a separate/discrete line (of a different colour) (1) 1
(ii) Calculation of frequency
Recall of v = f λ (1)
14
Correct answer [f = 5.1 × 10 Hz] (1) 2
Example of calculation:
v=fλ
8 –1 –9
3.0 × 10 m s = f × 589 × 10 m
14
f = 5.1 × 10 Hz
(c) Explanation of different colours
different colours = different freq/wavelengths / photons of different
energies (1)
photon energy/frequency/wavelength depends on difference between
energy levels (1)
diff atoms have diff energy levels/diff differences in levels (1) 3
(d) Explanation of transverse waves
variation in E or B-field /oscillations/vibrations/displacement
at right angles/perpendicular to direction of travel/propagation
st rd
[not just motion or movement for both 1 and 3 part] (1) 1
[9]
12. (a) (i) Energy level diagram:
• Arrow showing electron moving from lower level to a
higher level (1)
• Arrow downwards from higher to lower level [must
show smaller energy change than upward arrow] (1) 2
(ii) Missing energy:
Causes a rise in temperature of a named item (1) 1
9. (iii) Range of energies:
–9
Minimum energy when λ = 400 × 10 m (1)
Use of f = c/λ (1)
Use of E = hf (1)
Correct answer [3.1 eV] (1)
[allow 3.0 – 3.3 eV for rounding errors] [no u.e] 4
8 –9
eg. f = 3 × 10 / 400 ×10
14
= 7.5 × 10 Hz
–19
E = hf = 5.0 × 10 J
E = 3.1 eV
(b) Detecting forgeries:
Forgery would glow / old painting would not glow (1) 1
[8]
13. (a) Solar Power
2
Use of P = Iπr [no component needed for this mark] (1)
Use of cos 40 or sin 50 (with I or A) (1)
2.2 [2 sf minimum. No ue] (1) 3
3 –2 –3 2
e.g. P=1.1 × 10 W m × cos 40 × π(29 × 10 m)
= 2.2 W
(b) Energy
Use of E = Pt (1)
4 4
1.8 × 10 J/2.0 × 10 J (1) 2
e.g. E = 2.2W × (2.5 × 3600 s)
4
= 2.0 × 10 J
[5]
14. (a) Graph
Straight line with positive gradient (1)
Starting the straight line on a labelled positive fo (1)
[Curved graphs get 0/2. Straight line below axis loses mark 2
unless that bit is clearly a construction line.] 2
10. (b) Work function
From the y intercept (1)
[Accept if shown on graph]
OR Given by gradient × f0 (or h × f0) [Provided that f0 is marked
on their graph, or they say how to get it from the graph]
OR Read f and Ek off graph and substitute into Ek = hf – φ
[Curved graph can get this mark only by use of hf0 or equation methods.] 1
(c) Gradient
Gradient equals Planck constant (1) 1
[Curved graph can’t get this mark]
[4]
15. (a) Wavelength
eV to J (1)
Use of ∆E = hf (1)
Use of c = fλ (1)
–11
1.8 × 10 [2 sf minimum. No ue] (1) 4
e.g. f =
3 –19 –1 –34
(–1.8 keV – (– 69.6 keV)) × (10 × 1.6 × 10 J keV ) / 6.6 × 10 J s
19
= 1.64 × 10 Hz
8 –1 19
λ = 3.00 × 10 m s /1.64 × 10 Hz
–11
= 1.8 × 10 m
(b) Type
X rays [Accept gamma rays] (1) 1
[5]
16. Meaning of energy level
Specific allowed energy/energies (of electron in an atom)(1) 1
Meaning of photon
Quantum/packet/particle of energy/radiation/light/electromagnetic wave (1) 1
Formula for photon energy
E2 – E1 (1) 1
[Allow E1 + Ephoton = E2]
11. Explanation of photon wavelengths
Same energy change / same energy difference / energy the same (1) 1
Meaning of coherent
Remains in phase / constant phase relationship(1) 1
17. (a) Explanation
QOWC (1)
UV/red photon (1) 2
EUV > ER / fuv (1)
EUV > Φ / fuv > fTH (so electron can break free) (1)
One photon absorbed by one electron (1)
Both metal plate and electron are negative or repel (each other) (1) max 2
(b) (i) Intensity red light increased
nothing / no discharge (1)
(ii) Intensity of UV increased
(Coulombmeter) discharges quicker (1) 2
(c) Max KE
Use of E = hc/λ (1)
–19
conversion of eV to J or vice versa i.e. appropriate use of 1.6 × 10 (1)
Subtraction hc/λ – Φ [must use same units] or use of full equation (1)
–19
max KE = 2.2 × 10 J (1) 4
[Candidates may convert photon energy to eV leading to max KE = 1.4 eV]
[10]
18. Explanation of ‘excited’
Electrons/atoms gain energy (1)
and electrons move to higher (energy) levels (1) 2
[Credit may be gained for diagrams in this and the next 3 parts]
Explanation of how radiation emitted by mercury atoms
Electrons (lose energy as they) drop to lower levels (1)
Emit photons / electromagnetic radiation (1) 2
Explanation of why only certain wavelengths are emitted
12. Wavelength (of photon) depends one energy (1)
Photon energy depends on difference in energy levels (1)
Levels discrete / only certain differences / photon energies possible (1) 3
(and therefore certain wavelengths)
Why phosphor emits different wavelengths to mercury
Different energy levels / different differences in energy levels (1) 1
Calculation of charge
Q = It (1)
= 0.15 A × 20 × 60s
= 180 C (1) 2
[10]
19. Example of light behaving as a wave
Any one of:
• diffraction
• refraction
• interference
• polarisation (1) 1
What is meant by monochromatic
Single colour / wavelength / frequency (1) 1
Completion of graph
Points plotted correctly [–1 for each incorrect point] (1) (1)
Line of best fit added across graph grid (1) 3
What eVs tells us
Maximum (1)
2
Kinetic energy of the electrons / ½ mv of electrons (1) 2
13. Threshold frequency for sodium
14
Correct reading from graph: 4.3 × 10 Hz (1) 1
14 14
[Accept 4.1 × 10 – 4.7 × 10 Hz]
Work function
–34 14
f = hf0 = 6.63 × 10 J s × 4.3 × 10 Hz (1)
–19
= 2.9 × 10 J [Allow ecf] (1) 2
Why threshold frequency is needed
• Electron requires certain amount of energy to escape from surface (1)
• This energy comes from one photon of light (1)
• E = hf (1) Max 2
[12]
20. Photoelectric effect
(a) Explanation:
Particle theory: one photon (interacts with) one electron (1)
Wave theory allows energy to ‘build up’, i.e. time delay (1) 2
(b) Explanation:
Particle theory: f too low then not enough energy (is released by
photon to knock out an electron) (1)
Wave theory: Any frequency beam will produce enough energy (to release an electron,
i.e. should emit whatever the frequency) (1) 2
[4]
14. 21. Description of photon
Packet/quantum/particle of energy [accept E = hf for energy] (1) (1)
[allow {packet/quantum/particle} of {light/e-m radiation/e-m wave} etc for (1) X] 2
[zero marks if error of physics such as particle of light with negative charge]
–20
Show that energy to move electron is about 8 × 10 J
W = QV (1)
–19
= 1.6 × 10 C × 0.48 V
–20
= 7.7 × 10 J [no ue] (1) 2
Calculate efficiency of photon energy conversion
–20 –19
Efficiency = (7.7 × 10 J ÷ 4.0 × 10 J) [ecf] (1)
= 0.19 or 19 % (1) 2
[6]
22. Diagram
One arrow straight down (from −3.84 to − 5.02) (1)
Two arrows down (from −3.84 to −4.53, then − 4.53 to − 5.02) (1) 2
Transition T
T from − 5.02 to − 1.85 upwards (1) 1
Kinetic energy values and explanation of what has happened to lithium atom
in each case
0.92 eV (1)
Atom stays in −5.02 (eV) level/nothing happens to it (1)
0.43 eV (1)
Atom excited to − 4.53 (eV) level (1) 4
Full credit is given to candidates who take the k.e. of the electron to be 0.92 J
after collision. Any TWO correct energies with correct statement.
[7]
23. Incident photon energies
Use of E = hf (1)
X
Use of c = f λ [ignore × 10 errors] (1)
÷ e (1)
For 320 nm E = 3.9 (eV) and 640 nm E = 1.9 (eV) (1) 4
15. Photocurrent readings
Work function of Al > 3.9 / energies of the incident photons
OR threshold frequency is greater than incident frequencies (1)
14
For Li (ϕ = 2.3 eV / f = 5.6 × 10 Hz / λ = 540 nm hence) a photocurrent
at 320 nm but not 640 nm (1)
If intensity × 5 then photocurrent × 5 (1) 3
Stopping Potential
KEmax = 4.00/3.88 –2.30 = 1.7/1.58 [ignore anything with only e] (1)
Vs = 1.7/1.58 V (1) 2
[9]
24. Ionisation energy
–19 –1
(10.4 eV) × (1.6 × 10 J eV ) (1)
–18
(–) 1.66 × 10 (J) (1) 2
Kinetic energy
0.4 (eV) (1) 1
Transition
Use of E = hc/λ (1)
3.9 (eV) (1)
Transition is from (–)1.6 eV to (–)5.5 eV 3
[6]
25. Deductions about incident radiations
(i) Radiations have same frequency/same wavelength/ same photon energy (1)
(ii) Intensity is greater in (a) than in (b) (1) 2
Sketch graph (c)
Line of similar shape, starting nearer the origin on negative V axis (1) 1
Maximum speed
Use of E = hf (1)
–19
Subtract 7.2 × 10 (J) (1)
2
Equate to ½ mυ (1)
6 –1
3.1 × 10 ms (1) 4
[7]
26. Wavelength
Distance between two points in phase (1)
16. Distance between successive points in phase (1) 2
[May get both marks from suitable diagram]
Sunburn more likely from UV
UV (photons) have more energy than visible light (photons) (1)
Since shorter wavelength / higher frequency (1) 2
What happens to atoms
Move up energy levels/excitation/ionization (1)
Correctly related to electron energy levels (1) 2
[6]
27. Error in circuit diagram
Cell needs to be reversed (1)
Any one point from:
• electrons released from the magnesium
• copper wire needs to be positive to attract electrons (1) 2
Completion of sentence
UV is made up of particles called photons (1) 1
UV and visible light
(i) UV has shorter wavelength/higher frequency/higher photon
energy (1)
(ii) Both electromagnetic radiation/both transverse waves/same
speed (in vacuum) (1) 2
Explanation of why low intensity UV light produces a current
Any three points from:
• reference to photons or E = hf
• frequency > threshold frequency
• electron must have sufficient energy to be released
• UV photons have more energy
• electron is released by ONE photon
• brighter light just means more photons (1) (1) (1) Max 3
17. Why current stopped
Glass prevents UV reaching magnesium (1) 1
[9]
28. Description
Electron (near surface of cathode) absorbs photon and gains energy (1)
Work function is energy needed for electron to escape from surface (1)
Electrons released in this way are called photoelectrons (1) 3
Lowest frequency of radiation
f0 = E/h (1)
= 2.90 × 10-19 J/6.63 × 10-34 J s (1)
= 4.37 × 1014 Hz (1) 3
Suitability of potassium
λ = 3 × 108 m s-1 / 4.37 × 1014 Hz [use of lowest frequency] (1)
6.86 × 10-7 m [with suitable comment] (1)
OR
f = 3 × 108 m s-1 / 4.0 ×10-7 and f = 3 × 108 m s-1 / 7.0 × 10-7 [uses
range of λ] (1)
f = 7.5 × 1014 Hz to 4.3 × 1014 Hz [with suitable comment] (1) 2
[Suitable comment – e.g. this is within range of visible light/almost
all of the visible light photons will emit photoelectrons]
Maximum kinetic energy
Use of E = hc/λ AND minimum wavelength (1)
Max photon energy = hc/λ = 6.63 × 10-34 J s × 3 × 108 m s-1/(400 ×
10-9m)
= 4.97 × 10-19 J [no u.e]
Max k.e. = max photon energy – work function [or use equation]
= 4.97 × 10-19 J – 2.90 × 10-19 J
= 2.07 × 10-19 J [allow ecf if wrong wavelength used] [no u.e] (1) 3
18. Why some photoelectrons will have less than this k.e.
One point from:
• photon energy might be transferred to electron below surface
• so some energy transferred to atoms on the way to surface
• hence electron leaves surface with less energy than max
• max is for electron from the surface
• lower energy photon responsible for emission (1) 1
[12]
29. Table
Radio waves Sound waves
Transverse Longitudinal
Travel much faster than sound Travel more slowly
(Can) travel in a vacuum Cannot travel in a vacuum
Can be polarised Not polarised
Electromagnetic Pressure/Mechanical wave
Any three of the above Max 3
Assumption
Attempt to calculate area (1)
–2 –2
Intensity = 0.02 kW m OR 20 W m (1)
Efficiency at collector is 100%/beam perpendicular to collector
Power
2
Use of I P/4πr (1)
17
Power = 3.3 × 10 W [ecf their I]
No energy “lost” due to atmosphere (not surroundings) OR Inverse
square applies to this situation (1)
More efficient method
Use a laser (maser) / reference to beaming/ray (1) 1
[10]
19. 30. Ionisation energy
–19
Use of × 1.6 × 10
–18
2.2 × 10 [No u.e.] (1) 2
Addition to diagram
(i) From 4 to 3 labelled R / (i) (1)
(ii) From 1 to 4 labelled A / (ii) (1) 2
Emission spectrum
Hydrogen ‘excited’ in a discharge/thin tube/lamp [not bulb] (1)
Viewed through a diffraction grating/prism/spectrometer (1)
Appearance of emission spectrum
A series of lines / colours on a dark background [accept bands] (1) 3
Region of spectrum
Radio/microwave (1) 1
Speed of galaxy and deduction
∆ λ = 8 (mm) / 211 - 203 (mm) (1)
8
Use of 3 × 10 (1)
7 –1
υ = 1. 1(4) × 10 ms [No e.c.f.] (1)
Moving towards Earth (us) (1) 4
[12]
31. Photoelectric effect
Any two features and explanation from the following:
Feature: Experiments show k.e(max) ∝ f, OR not intensity
[Accept depends upon] (1)
Explanation: Photon energy ∝ f (1)
[Consequent]
k.e(max) ∝ intensity is a wave theory (1)
20. Feature: Emission of photoelectrons immediate (1)
Explanation: One photon releases one electron particle theory (1)
[Consequent] Wave theory allows energy to “build up” (1)
Feature: (Light) below a threshold frequency cannot release
electrons (1)
Explanation: Particle theory-f too low as not enough energy is released
[Consequent] by photon to knock out an electron (1)
Wave theory- if leave a low frequency beam on long
enough, it will produce enough energy to release an
electron (1)
[Max 5]
32. Planck constant
Realise that h is the gradient
Correct attempt to find gradient [but ignore unit errors here]
–34
h = (6.3 to 6.9) × 10 J s [No bald answers] 3
Work function
Use of hf0 / use intercept on T axis/use of φ = hf – T (1)
–19
φ = (3.4 to 3.9) × 10 J [ -1 if –ve] [2.1 to 2.4 eV] (1) 2
[5]
33. Energy of photon of light
E = hf = 6.63 × 10–34 J s × 6.0 × 1014 Hz = 3.98 × 10–19 (J) 1
Graph
Points correct (± ½ square) (2)
Single straight line of best fit (NOT giving intercept below 4.5 × 1014) (1)
Line drawn as far as f axis (1) 4
Value for h
Large triangle [at least 7 cm on K.E. axis] (1)
Gradient = e.g. (6.05 – 4.55) × 10 14 / 1.0 × 10–19 = 1.5 × 1033 (1)
h = 1/gradient = 6.67 × 10–34 J s (1) 3
21. Value of φ
Reading co-ordinates of a fixed point on graph (e.g. 0, 4.55 × 1014) (1)
φ from equation, e.g.
so φ = frequency intercept × h
= e.g. 4.55 × 1014 × 6.67 × 10–34
= 3.03 × 10–19 J (1) 2
Explanation
Not enough energy [OR frequency too low]
For 2nd mark, numerical/added detail required,
e.g calculation: E = 6.63 × 10–34 × 4.5 × 1014 Hz = 2.98 × 10–19 < φ
OR threshold frequency read from graph 2
[12]
34. Explanation of “coherent”
In / constant phase (difference) (1)
symbol 51 f "Monotype Sorts" s 123 (1) 1
Power delivered by laser
40
P= (1)
400 × 10 −15
= 1 × 1014 W (1) 2
Energy level change
3 × 10 8
υ = fλ / f = [–1 if omit 10–9] (1)
1050 × 10 −9
3 × 10 8
Use of E = hf / 6.6 × 10–34 × (1)
1050 × 10 −9
[If f = 1/T used, give this mark]
= 1.9 × 10–19 J (1) 3
[6]
22. 35. Calculation:
E = hc/λ [seen or implied] (1)
physically correct substitutions (1)
–19 –1
÷ 1.6 × 10 eV J (1)
5.78 eV (1) 4
Maximum kinetic energy:
3.52 eV [ecf but not if –ve.] (1)
Stopping potential:
3.52 V [Allow e.c.f., but not signs] (1) 2
Annotated graph:
Position of S (1)
Cuts V axis between origin and existing graph (1)
Similar shape [I levels off up/below existing line] (1) 3
[9]
36. Energy of photon of green light:
c 3 × 10 8 m s –1
f= = = 5.38 × 1014 Hz (1)
λ 5.58 × 10 – 7 m
E = hf = 6.63 × 10–34 J s × 5.38 × 1014 Hz (1)
= 3.56 × 10–19 J 2
Diagram:
Larger gap identified (1)
Downwards arrow between levels of same element (1)
2
[4]
37. Diffraction:
The spreading out of waves when they pass through a narrow slit or around an object (1)
Superposition:
Two or more waves adding (1)
to give a resultant wave [credit annotated diagrams] (1)
Quantum:
A discrete/indivisible quantity (1) 4
23. Particles:
Photon/electron (1) 1
What the passage tells us:
Any 2 points from:
• large objects can show wave-particle duality
• quantum explanations now used in “classical” solutions
• quantum used to deal with sub-atomic particles and
classical with things we can see Max 2
[7]
38. Ionisation energy of atomic hydrogen:
–18
13.6 eV OR 2.18 × 10 J [– sign, X] (1)
1
Why energy levels are labelled with negative numbers:
Work/energy is needed to raise the electrons/atoms to an energy of 0 eV, so
must start negative (1)(1)
OR
Work/energy is given out when the electrons/atoms move to the ground
state, so energy now less than 0, i.e. negative (1)(1)
OR
the ground state is the most stable/lowest energy level of the
electrons/atoms and must be less than 0, i.e. negative (1)(1)
2
st –
[1 mark essential: e highest/maximum/surface/ionised/free has
energy = 0eV
nd
2 mark: raising levels means energy in OR falling levels means energy out ∴ negative
levels]
24. Wavelength of photon:
∆E = 1.89 (eV) (1)
–19
Convert ∆E to joules, i.e. ×(1.6 × 10 )
OR
6.63 × 10 −34 × 3 × 10 8
λ= [Their E] (1)
1.89 (× 1.6 × 10 −19 )
–7
= 6.6 × 10 (m) [6.5 – 6.7] (1)
3
Production of line spectrum of atomic hydrogen in a laboratory:
Source – hydrogen discharge tube/hydrogen lamp/low p hydrogen with
high V across (1)
(view through) diffraction grating/prism/spectrometer/spectroscope (1)
2
Sketch:
A few vertical lines on a blank background OR sharp bands
Dark on light/light on dark NOT equally spaced (1)
1
Absorption spectrum:
White light through gas in container (1)
Diffraction grating/prism/spectrometer (1)
Must be dark lines on bright background (1)
[9]
25. 39. Threshold wave:
Electron requires certain amount of energy to escape from surface (1)
This energy comes from one photon (1)
Use of E = hf (1)
(So photon needs) minimum frequency (1)
Hence maximum wavelength
OR use of E = hc/λ (1) Max 4
Work function:
f = c/λ = 3.0 × 108 / 700 × 10–9 m (1)
= 4.28 × 10 14 Hz (1)
E = hf = 6.63 ×10–34 J s × 4.28 × 10 14 Hz = 2.84 × 10–19 (J) [Allow e.c.f.] (1) 3
Circuit :
Circuit showing resistors only in series (1)
Potentials labelled (1)
[Use of potential divider – allowed]
Resistor values 1: 1: 1 OR 1:2 (1) Max 2
Suggestion:
Cosmic rays travel more slowly than light (1) 1
[10]
40. Calculation of kinetic energy:
3 × 10 8 m s –1 –17
f= (E = hf = 1.63 ×10 J) (1)
λ
–19
φ converted to J: 6.20 × 1.6 × 10 OR Photon energy converted to
eV: 1.63 ÷ 1.6 × 10
(Subtract to obtain kinetic energy)
–17
Kinetic energy = (1.5 – 1.56) × 10 J[OR 95.7/97.4 eV]
[Beware 1.6398 0/3; > 101 eV 0/3]
26. Demonstration of speed of electrons:
–17 –31 2
1.53 × 10 J = ½ × 9.11 × 10 kg × υ (1)
[e.c.f their kinetic energy in joules]
υ = 5.8 × 106 m s–1 (1)
[If υ is not between 5 and 7 must comment to get mark]
[5]
41. Explanation of line spectra:
Specific frequencies or wavelengths (1)
Detail, e.g. absorption/emission (1)
OR within narrow band of wavelengths 2
Explanation how line spectra provide evidence for existence or energy levels in atoms:
Photons (1)
Associated with particular energies (1)
Electron transitions (1)
Discrete levels (to provide line spectra) (1) 3
[5]
42. Explanation:
Photons/quanta
Photon releases / used electron
Energy/frequency of red < energy/frequency of ultra violet
Red insufficient energy to release electrons so foil stays 4
Ultraviolet of greater intensity: foil/leaf collapses quicker/faster
Red light of greater intensity: no change/nothing 2
Observations if zinc plate and electroscope were positively charged:
Foil rises or Foil stays same/nothing
as electrons released it becomes more Released electrons attracted back by
positive positive plate/more difficult to
release electrons 2
[8]
27. 43. Energy level diagram:
0 eV
– 1 .5 1 e V
– 3 .3 9 e V
– 1 3 .6 V
− 13.6 → 0
− 1.51 → 0 AND − 3.39 → 0 ONLY 2
Why level labelled − 13.6 eV is called ground state:
Correct reference to stability/lowest energy state/level of
the electron/ atom/hydrogen 1
Transition which would result in emission of light of wavelength 660 nm:
3 × 10 8 ms –1
Correct use of c =fλ or E = hc/λ or f =
660 × 10 – 9 m
–19
Correct use of eV/J i.e. ÷ 1.6 × 10
∆E = 1.88
Transition = 1.5 → 3.39
[May be a downward arrow on diagram] 4
[7]
28. 44. Use of graph to estimate work function of the metal:
–34 14
φ= (6.63 × 10 J s) (6.0 × 10 Hz) – (some value)
–19
Value in brackets: (1.6 × 10 × 0.5 J)
–19
3.2 × 10 J or 2 eV 3
Addition to axes of graph A obtained when intensity of light increased:
A starts at –0.5
A → larger than /max
Addition to axes of graph B obtained when frequency of light increased:
B starts at less than – 0.5
B → same of lower than /max 4
[7]
45. Ionisation energy:
2810 eV (4.5 ×10–16 J) (1)
Calculation of maximum wavelength:
Energy in eV chosen above converted to joules (1)
Use of λ = c/f (1)
Maximum wavelength = 4.4 × 10–10 m (1)
Part of electromagnetic spectrum:
γ-ray / X-ray (1) 5
Calculation of the de Broglie wavelength:
λ = h/p p identified as momentum (1)
Either m or υ correctly substituted (1)
Wavelength = 1.1 × 10–13 m (1) 3
[Total 8 marks]
46. Experiments on the photoelectric effect show that
• the kinetic energy of photoelectrons released depends upon the frequency of the incident
light and not on its intensity,
• light below a certain threshold frequency cannot release photoelectrons.
29. How do these conclusions support a particle theory but not a wave theory of light?
Particle theory: E = hf implied packets/photons (1)
One photon releases one electron giving it k.e. (1)
Increase f ⇒ greater k.e. electrons (1)
Lower f; finally ke = O ie no electrons released Waves (1)
Energy depends on intensity / (amplitude)2 (1)
More intense light should give greater k.e–NOT SEEN (1)
More intense light gives more electrons but no change in maximum kinetic
energy (1)
Waves continuous ∴ when enough are absorbed electrons should be
released–NOT SEEN (1)
(6 marks)
Calculate the threshold wavelength for a metal surface which has a work function of 6.2 eV.
6.2eV × 1.6 × 10–19 C (1)
hc
Use of λ = (1)
E
Threshold wavelength = 2.0 × 10–7 m (1)
To which part of the electromagnetic spectrum does this wavelength belong?
UV ecf their λ (1)
(4 marks)
[Total 10 marks]