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The Plasma State of Matter

What is a Plasma?

Plasma is one of four states of matter. The other three states of
matter are solid, liquid, and gas. The term "plasma" has nothing to do
with blood plasma. Plasma, the least familiar state of matter to us
here on Earth, is actually the most common form of matter in the
universe.

Plasma makes up 99% of all visible matter in our universe. Although
naturally occurring plasma is rare on Earth, [LINK] there are many
man-made examples. Inventors have used plasma to conduct electricity
in neon signs and fluorescent bulbs. Scientists have constructed
special chambers to experiment with plasma in laboratories.

The Tokamak fusion reactor, courtesy of the Princeton Plasma Physics
Laboratory.

Plasma is relatively rare on Earth, occurring only in lightning
discharges and in artificial devices like fluorescent lights.
[LINK] Plasma is everywhere in our space environment, however.
Examples include:
* The aurora, or northern lights, flickering in the uppermost
reaches of Earth's atmosphere. (Aurora photo courtesy of David
Fritts © 1995.)
* [LINK] The solar wind generates an immense sheet of electrical
current that spirals like a ballerina's skirt as the Sun rotates.
(Artist's impression courtesy of Tom Potemra.)
* [LINK] The Sun itself, all other stars in our galaxy, and colossal
exploding jets from distant galaxies. (The X-ray image of the Sun
shown here is from the Japanese Yohkoh satellite, courtesy of
Lockheed Palo Alto Research Lab.)

[LINK] 

Hannes Alfvén (1908-1995), a Swedish physicist, is the father of
modern day plasma science. He believed that the effects of electricity
and magnetism played important roles in many astrophysical domains. He
received the Nobel Prize in 1970 for his contributions to basic plasma
physics and for his studies of space plasmas.

How are Plasmas Created?

Plasma, like ordinary matter, is made up of atoms.

Atoms are so tiny that more than a million can fit across the head of
a pin. They are composed of one or more negatively charged electrons
that orbit a positively charged nucleus (made up of neutral particles,
called neutrons, and positively charged particles, called protons).
Atoms are electrically neutral; they have the same number of positive
and negative electrical charges.

When gases are exposed to enough heat or other radiation, their
electrically neutral atoms split into positively charged fragments
called ions and negatively charged free electrons. Another term for
plasma is "ionized gas". Because plasma consists of electrically
charged particles, it acts very differently from ordinary forms of
gas. 

What are electric and magnetic fields?

A field is an influence or force that exists throughout space, that
one body exerts on another. Gravity is one such field. All matter
responds to gravity, but if matter is electrically charged or contains
currents, it also responds to electric and magnetic forces.

Electric charges and changing magnetic fields produce electric fields.
Here on Earth, we have learned how to produce electricity by using
motors, called generators, that cause magnetic fields to change. These
changing magnetic fields create the electric current we use in our
homes.

Electric charges in motion (an electric current) and changing electric
fields produce magnetic fields. For instance, flows of molten metals
deep inside Earth's core cause currents which sustain a huge magnetic
field that extends far into space.

[LINK] As seen in the diagram at left, magnetic fields are represented
by lines of force. When the lines are close together, the force of the
field is great; when they are far apart, the force is weak. Earth's
magnetic field lines spread out from the south polar region and come
together in the north polar region. (Diagram courtesy of Marshall
Space Flight Center/NASA.)

Understanding how plasmas interact with electric and magnetic fields
gives us a better idea of what is happening between the Sun and Earth
and elsewhere in the universe, but many mysteries remain.

Can Plasmas Be Controlled?

For over 30 years, scientists and engineers in many different
countries have tried to create a fusion reactor that produces more
energy than it [LINK] consumes. All atoms have a dense nucleus.
Fission and fusion reactions are two ways a nucleus changes.

The plasma discharge inside Princeton's Tokamak Fusion Reactor.
(Courtesy of the Princeton Plasma Physics Laboratory.)

A fission reaction occurs when heavy radioactive nuclei like uranium
split apart or "decay" into lighter nuclei. The excess energy can be
used to operate a nuclear power plant or in a more sinister way it can
produce the incredible energy in a nuclear explosion.

A fusion reaction, on the other hand, occurs when hydrogen nuclei
collide and form a heavier nucleus like helium. More energy is
required to "ignite"a fusion reaction, but when ignited the excess
energy is far greater than in a fission reaction. The only fuel
required in a fusion reactor is the heavy hydrogen found in seawater,
a virtually limitless source of energy. If controlled fusion were to
become reality it would be one of the great breakthroughs for
civilization. The scientific and engineering problems associated with
a fusion reactor are great. They can be divided into three categories:
1. Confinement (how long does the plasma stay around?)
2. Heating (does the plasma get hot enough?)
3. Technology (reactor design -- many problems remain for future
research)

You can learn about the U.S. fusion program by contacting the
Princeton Plasma Physics Laboratory, the Lawrence-Livermore National
Laboratory, and the Plasma Science & Technology home pages.

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