The
X-Ray Machine
The heart of an X-ray machine is an electrode
pair -- a cathode and an anode -- that sits inside
a glass vacuum tube. The cathode is a heated filament,
like you might find in an older fluorescent lamp.
The machine passes current through the filament,
heating it up. The heat sputters electrons off of
the filament surface. The positively-charged anode,
a flat disc made of tungsten, draws the electrons
across the tube.
The voltage difference
between the cathode and anode is extremely high,
so the electrons fly through the tube with a great
deal of force. When a speeding electron collides
with a tungsten atom, it knocks loose an electron
in one of the atom's lower orbitals. An electron
in a higher orbital immediately falls to the lower
energy level, releasing its extra energy in the
form of a photon. It's a big drop, so the photon
has a high energy level -- it is an X-ray photon.
The free electron collides with the tungsten atom,
knocking an electron out of a lower orbital. A higher
orbital electron fills the empty position, releasing
its excess energy as a photon.
Free electrons
can also generate photons without hitting an atom.
An atom's nucleus may attract a speeding electron
just enough to alter its course. Like a comet whipping
around the sun, the electron slows down and changes
direction as it speeds past the atom. This "braking"
action causes the electron to emit excess energy
in the form of an X-ray photon.
The free electron is attracted to the tungsten atom
nucleus. As the electron speeds past, the nucleus
alters its course. The electron loses energy, which
it releases as an X-ray photon.
The high-impact
collisions involved in X-ray production generate
a lot of heat. A motor rotates the anode to keep
it from melting (the electron beam isn't always
focused on the same area). A cool oil bath surrounding
the envelope also absorbs heat.
The entire mechanism
is surrounded by a thick lead shield. This keeps
the X-rays from escaping in all directions. A small
window in the shield lets some of the X-ray photons
escape in a narrow beam. The beam passes through
a series of filters on its way to the patient.
A camera on the
other side of the patient records the pattern of
X-ray light that passes all the way through the
patient's body. The X-ray camera uses the same film
technology as an ordinary camera, but X-ray light
sets off the chemical reaction instead of visible
light. (See How Photographic Film Works to learn
about this process.)
Generally, doctors
keep the film image as a negative. That is, the
areas that are exposed to more light appear darker
and the areas that are exposed to less light appear
lighter. Hard material, such as bone, appears white,
and softer material appears black or gray. Doctors
can bring different materials into focus by varying
the intensity of the X-ray beam.
Are X-Rays Bad
For You?
X-rays are a wonderful addition to the world of
medicine; they let doctors peer inside a patient
without any surgery at all. It's much easier and
safer to look at a broken bone using X-rays than
it is to open a patient up.
But X-rays can
also be harmful. In the early days of X-ray science,
a lot of doctors would expose patients and themselves
to the beams for long periods of time. Eventually,
doctors and patients started developing radiation
sickness, and the medical community knew something
was wrong.
The problem is
that X-rays are a form of ionizing radiation. When
normal light hits an atom, it can't change the atom
in any significant way. But when an X-ray hits an
atom, it can knock electrons off the atom to create
an ion, an electrically-charged atom. Free electrons
then collide with other atoms to create more ions.
An ion's electrical
charge can lead to unnatural chemical reactions
inside cells. Among other things, the charge can
break DNA chains. A cell with a broken strand of
DNA will either die or the DNA will develop a mutation.
If a lot of cells die, the body can develop various
diseases. If the DNA mutates, a cell may become
cancerous, and this cancer may spread. If the mutation
is in a sperm or an egg cell, it may lead to birth
defects. Because of all these risks, doctors use
X-rays sparingly today.
Even with
these risks, X-ray scanning is still a safer option
than surgery. X-ray machines are an invaluable tool
in medicine, as well as an asset in security and
scientific research. They are truly one of the most
useful inventions of all time.
