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National Ignition Facility
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It’s been sought after for 60 years. The idea
of obtaining the immense quantities of heat made possible by the fusion of two
atoms into a single helium atom, the very fuel which drives the stars.
http://www.fuel2000.net/starsteps2.pdf APPLYING THE FIELD
............................... AFTER 100 YEARS OF E=MC2, SCIENTISTS ARE STILL GLUED TO THE QUAINT, IMMATURE, AND OUTDATED CONCEPTS OF "HEAT", "BOOM", "BANG", "DEADLY RADIATION" NUCLEAR APPLICATIONS. IT IS HIGH TIME TO FLOW WITH FIELD APPLICATIONS
http://freedomtimes.blogspot.com/2009/07/national-ignition-facility-crystals.html
For years,
scientists have been trying to replicate the type of nuclear fusion that occurs
naturally in stars in laboratories here on Earth in order to develop a clean
and almost limitless source of energy.
Two different
research teams report significant headway in achieving inertial fusion
ignition—a strategy to heat and compress a fuel that might allow scientists to
harness the intense energy of nuclear fusion. One team used a massive laser
system to test the possibility of heating heavy hydrogen atoms to ignite. The
second team used a giant levitating magnet to bring matter to extremely high densities
— a necessary step for nuclear fusion.
Unlike nuclear fission, which tears apart atoms to release
energy and highly radioactive by-products, fusion involves putting immense
pressure, or “squeezing” two heavy hydrogen atoms, called deuterium and tritium
together so they fuse. This produces harmless helium and vast amounts of energy.
Recent experiments at the National Ignition Facility in Livermore,
California used a massive laser system the size of three football fields.
Siegfried Glenzer and his team aimed 192 intense laser beams at a small
capsule—the size needed to store a mixture of deuterium and tritium, which upon
implosion, can trigger burning fusion plasmas and an outpouring of usable
energy. The researchers heated the capsule to 3.3 million Kelvin, and in doing
so, paved the way for the next big step: igniting and imploding a fuel-filled
capsule.
In a second report released
earlier this week, researchers used a Levitated Dipole Experiment, or LDX, and
suspended a giant donut-shaped magnet weighing about a half a ton in midair
using an electromagnetic field. The researchers used the magnet to control the
motion of an extremely hot gas of charged particles, called a plasma, contained
within its outer chamber.
The donut magnet creates a
turbulence called “pinching” that causes the plasma to condense, instead of
spreading out, which usually happens with turbulence. This is the first time
the “pinching” has been created in a laboratory. It has been seen in plasma in
the magnetic fields of Earth and Jupiter. A much bigger ma LDX would have to be
built to reach the density levels needed for fusion, the scientists said.
Unlike nuclear fission, which tears apart atoms to release energy and highly radioactive by-products, fusion involves putting immense pressure, or “squeezing” two heavy hydrogen atoms, called deuterium and tritium together so they fuse. This produces harmless helium and vast amounts of energy.
Recent experiments at the National Ignition Facility in Livermore, California used a massive laser system the size of three football fields. Siegfried Glenzer and his team aimed 192 intense laser beams at a small capsule—the size needed to store a mixture of deuterium and tritium, which upon implosion, can trigger burning fusion plasmas and an outpouring of usable energy. The researchers heated the capsule to 3.3 million Kelvin, and in doing so, paved the way for the next big step: igniting and imploding a fuel-filled capsule.