The story for Transformers: Devastation sees you play as one of five Autobots; Optimus Prime, Grimlock, Sideswipe, Wheeljack and Bumblebee as they fight to stop Megatron and his decepticon army from terra forming the Earth into a new Cybertron and taking control of a new power source
called Plasma energy.
Not exact matches
By arranging their detectors at the edge of a fusion device, researchers have found that they are able to measure high
energy particles kicked out of the
plasma by a type of wave that exists in fusion
plasmas called an Alfvén wave (named after their discoverer, the Nobel Prize winner Hannes Alfvén).
In this new work, Wang's team refined a probe that makes use of a phenomenon researchers at Berkeley Lab first theoretically outlined 20 years ago:
energy loss of a high -
energy particle,
called a jet, inside the quark gluon
plasma.
DOE previously funded such approaches through a program
called High
Energy Density
Plasma (HEDP).
Does matter break down into a soup of subatomic particles —
called a quark - gluon
plasma — and then into
energy?
We don't know for sure, but of the, what I
call, baryonic matter, which is 5 percent of the total mass
energy density of the universe, one would guess about 90 or 95 percent of it, is in the form of ionized gas
called plasma.
The results, demonstrated by scientists at the U.S. Department of
Energy's (DOE) Princeton
Plasma Physics Laboratory (PPPL) and collaborators on China's Experimental Advanced Superconducting Tokamak (EAST) found that lithium powder can eliminate instabilities known as edge - localized modes (ELMs) when used to coat a tungsten plasma - facing component called the «divertor» — the unit that exhausts waste heat and particles from plasma that fuels fusion reac
Plasma Physics Laboratory (PPPL) and collaborators on China's Experimental Advanced Superconducting Tokamak (EAST) found that lithium powder can eliminate instabilities known as edge - localized modes (ELMs) when used to coat a tungsten
plasma - facing component called the «divertor» — the unit that exhausts waste heat and particles from plasma that fuels fusion reac
plasma - facing component
called the «divertor» — the unit that exhausts waste heat and particles from
plasma that fuels fusion reac
plasma that fuels fusion reactions.
Berkeley Lab was home to a pioneering experiment) in 2004 that showed laser
plasma acceleration can produce relatively narrow
energy spread beams - reported in the so -
called «Dream Beam» issue of the journal Nature - and in 2006 used a similar laser - driven acceleration technique to accelerate electrons to a then - record
energy of 1 billion electron volts, or GeV.
Physicist Sam Lazerson of the US Department of
Energy's Princeton Plasma Physics Laboratory has teamed with German scientists to confirm that the Wendelstein 7 - X fusion energy device called a stellarator in Greifswald, Germany, produces high - quality magnetic fields that are consistent with their complex d
Energy's Princeton
Plasma Physics Laboratory has teamed with German scientists to confirm that the Wendelstein 7 - X fusion
energy device called a stellarator in Greifswald, Germany, produces high - quality magnetic fields that are consistent with their complex d
energy device
called a stellarator in Greifswald, Germany, produces high - quality magnetic fields that are consistent with their complex design.
Fusion
energy is based on the same process that takes place in the sun, where gravity holds together the hot ionized gas
called a
plasma and nuclei of hydrogen collide together often enough that they occasionally overcome forces keeping them apart,
called the Coulomb forces, to fuse together and create a burst of
energy, Synakowski explained.
Berkeley Lab was home to a pioneering experiment in 2004 that showed laser
plasma acceleration can produce relatively narrow
energy spread beams — reported in the so -
called «Dream Beam» issue of the journal Nature — and in 2006 used a similar laser - driven acceleration technique to accelerate electrons to a then - record
energy of 1 billion electron volts, or GeV.
Researchers at the U.S. Department of
Energy's Princeton
Plasma Physics Laboratory (PPPL) have for the first time simulated the formation of structures
called «plasmoids» during Coaxial Helicity Injection (CHI), a process that could simplify the design of fusion facilities known as tokamaks.
William Fox, a researcher at the U.S. Department of
Energy's Princeton
Plasma Physics Laboratory, and his colleague Gennady Fiksel, of the University of Rochester, got an unexpected result when they used lasers in the Laboratory to recreate a tiny version of a gigantic plasma tsunami called a «shock wave.&
Plasma Physics Laboratory, and his colleague Gennady Fiksel, of the University of Rochester, got an unexpected result when they used lasers in the Laboratory to recreate a tiny version of a gigantic
plasma tsunami called a «shock wave.&
plasma tsunami
called a «shock wave.»
Together they have revolutionized a key instrument in the quest to harness fusion
energy — a device
called an X-ray crystal spectrometer that is used around the world to reveal strikingly detailed information about the hot, charged
plasma gas that fuels fusion reactions.