DP Physics (last assessment 2024)

Question 22M.2.HL.TZ1.9

Date	May 2022	Marks available	[Maximum mark: 10]	Reference code	22M.2.HL.TZ1.9
Level	HL	Paper	2	Time zone	TZ1
Command term	Estimate, Outline, Show that, Write down	Question number	9	Adapted from	N/A

[Maximum mark: 10]

22M.2.HL.TZ1.9

Potassium-40 $({}_{19}^{40}K)$ decays by two processes.

The first process is that of beta-minus (β⁻) decay to form a calcium (Ca) nuclide.

(a)

Write down the equation for this decay.

[2]

Markscheme

${}_{20}^{40}{Ca}$ ✓

${}_{- 1}^{0}e + {\bar{ν}}_{e}$ OR ${}_{- 1}^{0}β + {\bar{ν}}_{e}$ ✓

Full equation ${}_{19}^{40}K \to {}_{20}^{40}{Ca} + {}_{- 1}^{0}e + {\bar{ν}}_{e}$

Examiners report

This question was very well done by candidates. The majority were able to identify the correct nuclide of Calcium and many correctly included an electron/beta particle and a properly written antineutrino.

Potassium-40 decays by a second process to argon-40. This decay accounts for 11 % of the total decay of the potassium-40.

Rocks can be dated by measuring the quantity of argon-40 gas trapped in them. One rock sample contains 340 µmol of potassium-40 and 12 µmol of argon-40.

(b.i)

Show that the initial quantity of potassium-40 in the rock sample was about 450 µmol.

[2]

Markscheme

total K-40 decayed = $\frac{12 μmol}{0.11} = 109$ «μmol» ✓

so total K-40 originally was 109 + 340 = 449 «μmol»✓

Examiners report

This was a "show that" question that was generally well done by candidates.

(b.ii)

The half-life of potassium-40 is 1.3 × 10⁹ years. Estimate the age of the rock sample.

[3]

Markscheme

ALTERNATIVE 1

$λ = \frac{ln (2)}{t_{\frac{1}{2}}}$ used to give 𝜆 = 5.3 x 10^-10 per year ✓

$340 = (449) (e^{- 5.3 \times 10^{- 10} \times t})$

$\ln (\frac{340}{449}) = - 5.3 \times 10^{- 10} \times t$ ✓

t = 5.2 x 10⁸ «years» ✓

ALTERNATIVE 2

$p = \frac{340}{449} = 0.76$ «remaining» ✓

$n = \frac{\ln (p)}{0.693} = \frac{\ln (0.76)}{0.693} = 0.40$ ✓

t = 0.40 x 1.3 x 10⁹ = 5.2 x 10⁸ «years» ✓

ALTERNATIVE 3

$p = \frac{340}{449} = 0.76$ «remaining» ✓

$0.76 = {(\frac{1}{2})}^{\frac{t}{1.3 \times 10^{9}}}$ ✓

t = 0.40 x 1.3 x 10⁹= 5.2 x 10⁸ «years» ✓

Allow 5.3 x 10⁸ years for final answer.

Allow ECF for MP3 for an incorrect number of half-lives.

Examiners report

This was a more challenging question for candidates. Many were able to calculate the decay constant and recognized that the ratio of initial and final quantities of the potassium-40 was important. A very common error was mixing the two common half-life equations up and using the wrong values in the exponent (using half life instead of the decay constant, or using the decay constant instead of the half life). Examiners were generous with ECF for candidates who clearly showed an incorrect number of half-lives multiplied by the time for one half-life.

(c)

Outline how the decay constant of potassium-40 was determined in the laboratory for a pure sample of the nuclide.

[3]

Markscheme

«use the mass of the sample to» determine number of potassium-40 atoms / nuclei in sample ✓

«use a counter to» determine (radio)activity / A of sample ✓

use A = λN «to determine the decay constant / λ» ✓

Examiners report

Describing methods of determining half-life continues to be a struggle for candidates with very few earning all three marks. Many candidates described a method more appropriate to measuring a short half- life, but even those descriptions fell far short of being acceptable.

Syllabus sections

Core

Core » Topic 7: Atomic, nuclear and particle physics » 7.1 – Discrete energy and radioactivity

Core » Topic 7: Atomic, nuclear and particle physics

Core » Topic 3: Thermal physics » 3.2 – Modelling a gas

Core » Topic 3: Thermal physics

Additional higher level (AHL)

Additional higher level (AHL) » Topic 12: Quantum and nuclear physics » 12.2 – Nuclear physics

Additional higher level (AHL) » Topic 12: Quantum and nuclear physics

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