Light travels as a wave of electromagnetic radiation. The colour of the light depends on its frequency. (i) Light is an example of a transverse wave. Explain what is meant by a transverse wave. (A labelled diagram may help your answer.) (ii) Orange light has a frequency of $5 imes 10^{14}$ Hz. The speed of light is $3 imes 10^{8} ext{ m s}^{-1}$. Calculate the wavelength of the orange light. Sound also travels as a wave. Sound is an example of a mechanical wave. (iii) Describe an experiment to show that sound needs a medium to travel through. (iv) What is meant by reflection? (v) Sound waves undergo reflection, refraction, diffraction and interference. (vi) Describe an experiment to show the interference of sound waves. (vii) Sound waves do not undergo polarisation. Explain why. As an ambulance passes a stationary observer, its siren emits a sound of a particular frequency. This frequency appears to change as the ambulance passes the observer. This is caused by the Doppler effect. (viii) Describe a laboratory experiment to demonstrate the Doppler effect. (ix) State one use of the Doppler effect.

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Light travels as a wave of electromagnetic radiation - Leaving Cert Physics - Question 9 - 2020

Question 9

Light travels as a wave of electromagnetic radiation. The colour of the light depends on its frequency. (i) Light is an example of a transverse wave. Explain what i... show full transcript

Worked Solution & Example Answer:Light travels as a wave of electromagnetic radiation - Leaving Cert Physics - Question 9 - 2020

Step 1

Explain what is meant by a transverse wave.

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Answer

A transverse wave is characterized by oscillations that are perpendicular to the direction of wave propagation. In this type of wave, the disturbance moves in a direction that is at right angles to the wave's energy transfer. A common example is light waves, where the electric and magnetic fields oscillate perpendicular to each other and to the direction of the wave.

Step 2

Calculate the wavelength of the orange light.

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Answer

To find the wavelength ( $\\lambda$ ) of orange light, we can use the formula:

ext{Speed} = ext{Frequency} imes ext{Wavelength} \\ \\lambda = \frac{v}{f}

Substituting the known values:

\\lambda = \frac{3 imes 10^{8} ext{ m/s}}{5 imes 10^{14} ext{ Hz}} = 6 imes 10^{-7} ext{ m}

Thus, the wavelength of orange light is $6 imes 10^{-7} ext{ m}$ .

Step 3

Describe an experiment to show that sound needs a medium to travel through.

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An experiment can be conducted using a bell jar and a vacuum pump. Start with the bell jar containing a ringing electric bell. First, allow the sound to be heard in air. Then, use the vacuum pump to remove the air from the bell jar. As the air is evacuated, the sound will fade until it becomes inaudible. This demonstrates that sound requires a medium (in this case, air) to travel through.

Step 4

What is meant by reflection?

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Reflection refers to the bouncing back of waves when they encounter a surface or an obstacle that does not absorb all the energy of the wave. This phenomenon is commonly observed with sound waves and light waves, leading to echoes and the perception of images, respectively.

Step 5

Describe an experiment to show the interference of sound waves.

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Answer

To observe the interference of sound waves, one can use two tuning forks of the same frequency. Strike both forks simultaneously and place them at a distance from the ear. As the sound waves propagate, they will overlap and create regions of constructive and destructive interference, resulting in variations in loudness. This can be demonstrated by moving to different positions to experience the differences in sound intensity.

Step 6

Sound waves do not undergo polarisation. Explain why.

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Answer

Sound waves are longitudinal waves, meaning the oscillations occur in the same direction as the wave travels. This characteristic makes it impossible for sound waves to be polarized, as polarization requires a transverse wave, where oscillations can be restricted to a particular plane.

Step 7

Describe a laboratory experiment to demonstrate the Doppler effect.

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A simple experiment to demonstrate the Doppler effect involves using a moving sound source, such as a buzzer, and a stationary observer. As the buzzer approaches the observer, the sound frequency increases, leading to a higher pitch. Conversely, as it moves away, the frequency decreases, resulting in a lower pitch. This effect can be portrayed by moving the sound-emitting device along a straight path past the observer.

Step 8

State one use of the Doppler effect.

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Answer

One application of the Doppler effect is in medical imaging, specifically in ultrasound. It is used to measure blood flow and determine the speed and direction of blood in clinical settings.

Light travels as a wave of electromagnetic radiation - Leaving Cert Physics - Question 9 - 2020

Worked Solution & Example Answer:Light travels as a wave of electromagnetic radiation - Leaving Cert Physics - Question 9 - 2020

Explain what is meant by a transverse wave.

Calculate the wavelength of the orange light.

Describe an experiment to show that sound needs a medium to travel through.

What is meant by reflection?

Describe an experiment to show the interference of sound waves.

Sound waves do not undergo polarisation. Explain why.

Describe a laboratory experiment to demonstrate the Doppler effect.

State one use of the Doppler effect.

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