Galactic Redshift
- In space, the Doppler effect of light can be observed when spectra of distant stars and galaxies are observed, this is known as:
- Redshift if the object is moving away from the Earth
- The wavelength is increasing but the frequency is decreasing
- Blueshift if the object is moving towards the Earth
- The wavelength is decreasing but the frequency is increasing
- Redshift if the object is moving away from the Earth
Stars and galaxies can be red or blueshifted to an observer on Earth
- Redshift is defined as:
The fractional increase in wavelength (or decrease in frequency) due to the source and observer receding from each other
- Redshift can be observed by comparing the light spectrum produced from a close object, such as our Sun, with that of a distant galaxy
- The light from the distant galaxy is shifted towards the red end of the spectrum (compared to the Sun's spectra)
- This provides evidence that the universe is expanding
Comparing the light spectrum produced by the Sun with light from a distant galaxy
Positive and Negative Velocities
- If the speed of the galaxy relative to Earth is positive then the galaxy is moving towards the Earth
- This is the case when the observed frequency f0 is greater than the reference frequency f
- If the speed of the galaxy relative to Earth is negative then the galaxy is moving away from the Earth
- This is the case when the observed frequency f0 is less than the reference frequency f
An Expanding Universe
- After the discovery of Doppler redshift, astronomers began to realize that almost all the galaxies in the universe are receding
- This led to the idea that the space between the Earth and the galaxies must be expanding
- This expansion stretches out the light waves as they travel through space, shifting them towards the red end of the spectrum
- The expansion of the universe can be compared to dots on an inflating balloon
- As the balloon is inflated, the dots all move away from each other
- In the same way, as the rubber stretches when the balloon is inflated, space itself is stretching out between galaxies
- Just like the dots, the galaxies move away from each other, however, they themselves do not move
- Another observation from looking at the light spectra produced by distant galaxies is that the greater the distance to the galaxy, the greater the redshift
- This means that the greater the degree of redshift, the faster the galaxy is moving away from Earth
The further a galaxy is from Earth, the greater its redshift tends to be
The furthest galaxies appear to be redshifted the most and are receding the fastest
Worked example
The spectra below show dark absorption lines against a continuous visible spectrum.
A particle line in the spectrum of light from a source in the laboratory has a frequency of 4.570 × 1014 Hz. The same line in the spectrum of light from a distant galaxy has a frequency of 4.547 × 1014 Hz.
Calculate the speed of the distant galaxy in relation to the Earth. State whether it is moving towards or away from the Earth.
Answer:
Step 1: Write down the known quantities
- Observed frequency, f0 = 4.547 × 1014 Hz
- Reference (source) frequency, f = 4.570 × 1014 Hz
- Shift in frequency, Δf = observed − source = (4.547 – 4.570) × 1014 = –2.3 × 1012 Hz
- Speed of light, c = 3.0 × 108 m s–1
Step 2: Write down the Doppler redshift equation
Step 3: Rearrange for speed v, and calculate
= –1.5 × 106 m s–1
Step 4: Write a concluding sentence
- The velocity is negative, so the source is moving away from the Earth
OR - The observed frequency is less than the source frequency, therefore, there is a decrease in frequency, so the source is receding, or moving away, from the Earth at 1.5 × 106 m s–1
Exam Tip
Keep travel of the minus signs in your calculation, as this gives you information about whether the object is moving away or towards the observer.
The speed of light is given in your data booklet, you will not need to memorise this value.