It is an interesting fact that the element helium, that
beloved of elements that makes your voice go all squeaky when you inhale it,
was discovered in the sun. Now, that's pretty impressive. What are some other
things that have been discovered? Thousands of years ago, humans discovered
that gone off fruit juice makes you feel merry, which we now know is because
yeast ferments the sugar into alcohol and that makes us drunk. Now there are a
number of reasons why that particular discovery could not have been made in the
sun, the most important being that the fruit, the yeast and the discoverer
would have been vaporised long before they got within even 100 miles of the
sun.
So how do you discover an element in the sun, and what does
it have to do with quantum physics? People often say that quantum physics was
the greatest discovery of the 20th century but what exactly does the expression
mean? It's a straight forward question but tricky to answer.
Physicists commonly say that a big part of quantum physics
is that small things don't behave like big things. They mean that sub-atomic
particles, the things that atoms are made of, don't behave like objects that we
can see, like snooker balls. Snooker balls follow Newtonian physics, the laws
discovered by Isaac Newton. For example, if you set a snooker ball moving, it
will move at a constant velocity until a force slows it down or changes its
direction. In practice, if you roll the ball along a snooker table, it will
immediately be slowed down by the friction between the ball and the surface of
the table, as well as the air resistance. If it hits another ball, both will
move away from each other with an equal and opposite force. So usually, however
much force is supplied to the two balls during the collision will be shared
equally between the two of them, causing them both to move off in different
directions and, usually, at similar speeds. These are key examples of Newtonian
physics.
But sub-atomic particles do not necessarily obey quantum
physics. The electron is an especially good example of this. When we draw
diagrams of atoms, like the one below, they often look as if the electrons
orbit the nucleus the way that planets orbit the sun. Orbiting planets do
demonstrate Newtonian physics - it is the force of gravity between the sun and
the planets that keeps each one in its individual orbit. No matter how the
diagrams look, however, electrons do not orbit the nucleus of the atom.
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| Figure 1: Diagrams showing the atomic structures of lithium, boron and fluorine. The electrons appear to orbit the nucleus but do not. These electron shells can also be called energy levels. |
A great analogy for the way electrons behave around nuclei
is the way moths behave around light bulbs at night. When moths detect a light
bulb, they fly towards it and end up flying around and around it until the bulb
is switched off. (The actual reason for this is that they are adapted to use
stars for navigation, so they basically confuse the light bulb for a star.)
Now, magnets are attracted to each other, or more accurately, the north pole of
a magnet is attracted to the south pole and vice versa. If you put two magnets
near each other on a table top, and nothing is in between them, they will move
towards each other until they are touching. Isn't this what it means to be
attracted to each other?
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Figure 2: A moth flying in an
erratic path near the lightbulb
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On the other hand, the moths are attracted to the lightbulb
but they do not fly towards it until they are touching it and then stay put on
its surface. Instead, they periodically crash into the lightbulb before
immediately flying away again but continuing to buzz around nearby. This is
very similar to how electrons move near nuclei. The negative electron is
attracted towards the positive nucleus but it does not move towards it until
they are both touching and then stay put. Instead, it follows an erratic path
in the vicinity of the nucleus, just like the moths near the light bulb.
As a final confuser, it is interesting to consider that
actually, even the two magnets are not technically touching. If you could see
the atoms in each of the magnets, you would see that they are not touching. At
the atomic level, there are both attractive and repulsive forces between
particles, so they simultaneously pull each other towards themselves while also
pushing each other away. Therefore, you end up with a little gap between them.
At the atomic level, there would be a little gap between the two magnets so
actually they are not touching. You may also have heard the idea that the human
body would be the same size as just a grain of sand if all of the space between
the subatomic particles were removed. The main source of this space is the gap
between the electrons and the atomic nuclei. This unexpected behaviour of the
electron forms a huge part of quantum physics.
To consider the way electrons move in more detail, it will
be helpful to consider what the word quantum means. A quantum is a discrete
quantity of energy. What that means is that it is a certain amount and it is
only that amount. You can imagine it like the price of some product that you
might want to buy in a shop. In some parts of the world, you can haggle over
the price, bargain until you get it a little bit lower. Well that kind of caper
wouldn't fly if it were a quantum price. If the price were £10 and you said,
"Will you do it for £8?" the answer would be: "No!" So
discrete means that you cannot divide the quantum into smaller parts; it
represents a certain quantity and it has to be just that quantity.
Going back to the electron, what do those circles in atomic
diagrams mean, the ones that make them look like orbiting planets? They
represent electron shells or, to use a really high level term, energy levels.
These energy levels provide some information about where the electron is but
they are more like zones than map
coordinates. Electrons dwell in something called an orbital and these are the
things like zones. What an orbital represents is a volume of space in which you
are likely to find an electron. It's like meeting a friend in town. If you say,
"I don't know exactly where I'll be but I'll be somewhere in town so if
you also come to town, at some point we'll run into each other," that's
kind of like the orbital. It doesn't say exactly where the electron is, but
gives you a rough idea of where it will be.
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Figure 3: As the electron drops from the second energy
level to the first energy level, a beam of electromagnetic radiation is
emitted.
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Now light is very complex stuff. Depending on what stage
you're at with learning science, you may know that white light can be separated
into the colours of the rainbow. You may also know that there are lots of kinds
of light that we cannot see, such as microwaves, which we can use to quickly
heat up food; then there is ultra violet light, that we can use to tan
ourselves; and infra red, which we can use to help our remote controls
communicate with our televisions. In fact, the proper name for all of these
different kinds of light is electromagnetic radiation.
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Figure 4: The wavelength of a wave. The value y
represents the amplitude. (Image adapted from the following Wikimedia Commons
file: Wave-i18n.png Author not known.)
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Radio waves have very long wavelengths whereas microwaves,
as the name suggests, have really teeny wavelengths. Here's another interesting
fact, it turns out that these different kinds of electromagnetic radiation also
have different energies. This makes sense if you think about it because if you
leave a jacket potato next to a radio, the radio waves won't make it much
hotter, but if you put the potato in a microwave, then it will get piping hot
pretty fast. (Although this would not be a “fair test” as the concentration of
radiation would be different in each case.)
Now we're ready to think about quanta (plural of quantum).
When an electron drops from a higher energy level to a lower energy level, it
emits a beam of light that corresponds exactly to the difference in energy
between the two energy levels. The value of that quantum of energy dictates the
wavelength, and therefore the type, of the beam of light. For example, if it is
a big quantum, it might emit a beam of ultra violet light, whereas a smaller
quantum could produce a beam of lower energy infra red light.
"Hang on a minute," readers might be thinking,
"I thought this quantum could have one value and one value only, so how
come different wavelengths of light can be produced?!" A quantum can
indeed have only one value but you can have different quanta. A key reason why
quanta can be different is that elements are different. If an electron drops
from the second energy level of a carbon atom to the first energy level, it is
always the same amount of energy that is produced. However, if the electron
drops from the second energy level of an oxygen atom to the first energy level,
it will give off a different amount of energy than the electron in the carbon
did. So, the quantum of energy is always the same for the same element, but if
you use a different element, the quantum will be a different size.
Now we are ready to consider how you discover an element in
the sun. Basically, helium was discovered by analysing the light emitted from
the sun. There is a lot of helium in the sun, for reasons which also relate to
quantum physics. When the light was analysed, scientists found a wavelength of
light that they had not detected from any element that had already been
discovered. The wavelength corresponded
to a quantum of energy that no known element had previously emitted so the only
possible conclusion was that there must exist in the sun an unknown element,
which was thus named helium, after Helios the sun god in ancient Greek
mythology. Helium was subsequently detected on earth a few years later,
confirming the prediction. And that is how you discover an element in the sun.
©Tom Husband 2014 All writing and all images, excepting the
image of the wave, attributed to Wikimedia Commons
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