THE ATOMIC HYDROGEN
EMISSION SPECTRUM
This page introduces the
atomic hydrogen emission spectrum, showing how it arises from electron
movements between energy levels within the atom. It also looks at how the
spectrum can be used to find the ionisation energy of hydrogen.
What is an emission
spectrum?
Observing hydrogen's
emission spectrum
A hydrogen discharge
tube is a slim tube containing hydrogen gas at low pressure with an electrode
at each end. If you put a high voltage across this (say, 5000 volts), the tube
lights up with a bright pink glow.
If the light is passed
through a prism or diffraction grating, it is split into its various colours.
What you would see is a small part of the hydrogen emission spectrum. Most of
the spectrum is invisible to the eye because it is either in the infra-red or
the ultra-violet.
The photograph shows part
of a hydrogen discharge tube on the left, and the three most easily seen lines
in the visible part of the spectrum on the right. (Ignore the
"smearing" - particularly to the left of the red line. This is caused
by flaws in the way the photograph was taken|
Extending hydrogen's
emission spectrum into the UV and IR
There is a lot more to
the hydrogen spectrum than the three lines you can see with the naked eye. It
is possible to detect patterns of lines in both the ultra-violet and
infra-red regions of the spectrum as well.
These fall into a
number of "series" of lines named after the person who discovered
them. The diagram below shows three of these series, but there are others in
the infra-red to the left of the Paschen series shown in the diagram.
The diagram is quite
complicated, so we will look at it a bit at a time. Look first at the Lyman
series on the right of the diagram - this is the most spread out one and
easiest to see what is happening.
The Lyman series is a
series of lines in the ultra-violet. Notice that the lines get closer and
closer together as the frequency increases. Eventually, they get so close
together that it becomes impossible to see them as anything other than a
continuous spectrum. That's what the shaded bit on the right-hand end of the
series suggests.
Then at one particular
point, known as the series limit, the series stops.
If you now look at the
Balmer series or the Paschen series, you will see that the pattern is just the
same, but the series have become more compact. In the Balmer series, notice the
position of the three visible lines from the photograph further up the page.
Complicating everything
- frequency and wavelength
You will often find the
hydrogen spectrum drawn using wavelengths of light rather than frequencies.
Unfortunately, because of the mathematical relationship between the frequency
of light and its wavelength, you get two completely different views of the
spectrum if you plot it against frequency or against wavelength. |
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