Outline how the standing wave is formed.

Draw an arrow on the diagram to represent the direction of motion of the molecule at X.

Label a position N that is a node of the standing wave.

The speed of sound is 340 m s^–1 and the length of the pipe is 0.30 m. Calculate, in Hz, the frequency of the sound.

The speed of sound in air is 340 m s^–1 and in water it is 1500 m s^–1.

The wavefronts make an angle θ with the surface of the water. Determine the maximum angle, θ_max, at which the sound can enter water. Give your answer to the correct number of significant figures.

Draw lines on the diagram to complete wavefronts A and B in water for θ < θ_max.

the incident wave «from the speaker» and the reflected wave «from the closed end»

superpose/combine/interfere

Allow superimpose/add up

Do not allow meet/interact

[1 mark]

Horizontal arrow from X to the right

MP2 is dependent on MP1

Ignore length of arrow

[1 mark]

P at a node

[1 mark]

wavelength is λ = «\(\frac{{4 \times 0.30}}{3}\) =» 0.40 «m»

f = «\(\frac{{340}}{{0.40}}\)» 850 «Hz»

Award [2] for a bald correct answer

Allow ECF from MP1

[2 marks]

\(\frac{{\sin {\theta _c}}}{{340}} = \frac{1}{{1500}}\)

θ_c = 13«°»

Award [2] for a bald correct answer

Award [2] for a bald answer of 13.1

Answer must be to 2/3 significant figures to award MP2

Allow 0.23 radians

[2 marks]

correct orientation

greater separation

Do not penalize the lengths of A and B in the water

Do not penalize a wavefront for C if it is consistent with A and B

MP1 must be awarded for MP2 to be awarded

[2 marks]