Model Doppler effect
The source emits waves at its own emitted frequency, but relative motion changes the spacing of wavefronts reaching the observer. Approaching motion makes successive wavefronts arrive closer together in time, so the detected frequency is higher. Receding motion makes them arrive farther apart in time, so the detected frequency is lower.
Choose the observed frequency change from the relative motion.
DecisionA sound source moves towards a stationary observer and then passes the observer. Describe the change in observed frequency before and after it passes.
Saying the emitted frequency changes instead of the observed frequency changing due to relative motion.
A sound source moves towards a stationary observer and then passes the observer. Describe the change in observed frequency before and after it passes.
ChooseModel Doppler wavefront diagrams
A Doppler wavefront diagram is a spacing map. Each wavefront was emitted at a different time, so a moving source changes where the centres of the circles are. Ahead of the source, wavefronts bunch up and the observer receives more wavefronts per second. Behind the source, they are spread out and the observer receives fewer wavefronts per second.
Label the Doppler wavefront diagram for a source moving to the right.
LabelA diagram shows wavefronts closer together in front of a moving source and farther apart behind it. Explain what an observer in each position detects.
Saying only “the waves are closer” without translating spacing into wavelength and observed frequency.
A diagram shows wavefronts closer together in front of a moving source and farther apart behind it. Explain what an observer in each position detects.
ChooseModel Light Doppler approximation
The light Doppler approximation is a small-shift rule. Measure how far the observed wavelength has moved from its rest value, divide by the rest wavelength, and multiply by c to estimate radial speed. Red shift means the observed wavelength is longer, so the source is moving away. Blue shift means the observed wavelength is shorter, so the source is moving towards the observer.
Build the low-speed light Doppler approximation using observed and rest wavelength.
FormulaA spectral line has laboratory wavelength 500 nm and is observed from a star at 501 nm. Estimate the radial speed of the star and state its direction of motion.
Using the observed wavelength as the denominator or forgetting that longer wavelength is red shift and recession.
A spectral line has laboratory wavelength 500 nm and is observed from a star at 501 nm. Estimate the radial speed of the star and state its direction of motion.
ChooseExplain Spectral line shifts
A spectral line acts like a wavelength marker. Because each element has known rest wavelengths, astronomers can compare observed line positions with laboratory positions. A uniform shift of the pattern to longer wavelengths is red shift, indicating recession. A shift to shorter wavelengths is blue shift, indicating approach. The shift gives radial velocity, not sideways motion across the sky.
Interpret the spectral line shift from laboratory and observed wavelengths.
GraphThe diagram shows laboratory spectral lines above observed spectral lines on a wavelength axis increasing to the right.
A hydrogen line with laboratory wavelength 486.1 nm is observed in a galaxy spectrum at 492.0 nm. State the type of shift and what it implies about the galaxy motion.
Calling it blue shift because the line is in the visible blue-green region, instead of comparing observed and laboratory wavelengths.
A hydrogen line with laboratory wavelength 486.1 nm is observed in a galaxy spectrum at 492.0 nm. State the type of shift and what it implies about the galaxy motion.
ChooseRetrieve the Core C.5 Doppler effect Model
ReviewCore C.5 is mostly a sign and representation topic. Decide whether source and observer are approaching or receding. Then translate that into wavefront spacing, observed wavelength, observed frequency, and spectral line movement. The light approximation uses fractional wavelength shift, while spectral line interpretation tells you the direction of radial motion.
Match each C.5 core cue to the Doppler interpretation it should trigger.
Match