Transcript JET
Controlled Nuclear Fusion
The JET Project
JET (Joint European Torus)
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and use it to fill in the concept map in your handouts.
Plasma
Steam to
turbines
Torus
Pump
Container
Blanket
Water
from
turbines
Plasma
It is a particular state of matter where the atoms are stripped of their electrons. In
this state the matter is made only of nuclei, so plasma is positively charged.
Therefore, it is capable of carrying an electric current. In D-T reactors a massive
current (106 A) is passed through the plasma to give the initial energy to start the
fusion reaction by heating the plasma to 108 K. Such high temperatures occur
naturally in the Sun and other stars, where the energy provided to the electrons in
the atoms is too high for the electrostatic forces from the protons in the nucleus to
keep hold of them.
Lithium blanket
The Lithium in the blanket is continually bombarded by the neutrons produced in
the fusion reaction. This gives rise to another nuclear reaction where the nuclei of
Lithium rearrange into He nuclei and Tritium, which is then collected in the core to
form part of the plasma. The He nuclei (alpha-particles) are soon after stopped by
the concrete container and later gain electrons, becoming Helium atoms. So, the
only waste product in a D-T reactor is Helium.
The constant bombardment and the closeness to the hot plasma increases the
temperature of the blanket to the order of 103 K.
Container
The container is a thick layer of concrete surrounding the blanket and the core of
the reactor. This layer stops the neutrons produced in the fusion reaction from
escaping from inside the reactor and harm the staff operating the machinery.
Torus
The torus is a doughnut shape designed to contain the plasma in a confined
space, so that the deuterium and tritium nuclei would not escape the core and the
intense heat would not affect other parts of the reactor. This is achieved through
strong and complicated magnetic field lines around the torus that force the plasma
to follow a closed loop. The plasma particles spiral around the field lines and
collide with one another. The plasma must be kept from touching the steel
container or it would fizzle out losing its energy.
JET (Joint European Torus)
Achieved by
massive current
(106 A)
Temperature
108 K
Forces plasma to
follow a complicated
path
Nuclei of D and T
stripped of their
electrons
Plasma
Plasma particles
stay in the core and
reaction is sustained
Steam to
turbines
Doughnut
shape
Torus
Pump
Container
Stops neutrons from
reaching staff
Tritium
Water
from
turbines
Blanket
Concrete
Neutrons
released in
the fusion
reaction
Lithium
Temperature
103 K
Use the grid below to compare a fission and a fusion reactor
Type of reactor
Nuclear
fission
Nuclear
fusion
Energy output
per nucleon
0.8 MeV
3 MeV
Advantages
Disadvantages
Waste remains
Relatively low
radioactive for
thousands of years
start-up energies
Non-renewable fuel
Technology
already developed resources
Lower energy output
Renewable fuel
resources
Harmless waste
products
Higher energy
output
Very high power
required for start-up
Technology not yet
developed