High Energy Density Sciences Division
A new way to observe this deformation as it happens can help study a wide range of phenomena, from meteor impacts to high-performance ceramics used in armor, as well as how to protect spacecraft from high-speed dust impacts.
SLAC’s X-ray laser and Matter in Extreme Conditions instrument allow researchers to examine the exotic precipitation in real time as it materializes in the laboratory.
Tripling the energy and refining the shape of optical laser pulses at LCLS’s Matter in Extreme Conditions instrument allows researchers to recreate higher-pressure conditions and explore unsolved questions relevant to fusion energy, plasma physics and materials science.
Zeeshan Ahmed, Frederico Fiuza and Emilio Nanni will each receive about $2.5 million over five years to pursue cutting-edge research into cosmic inflation, plasma acceleration and using terahertz waves to accelerate particles.
Frederico Fiuza and his team are conducting thorough investigations of plasma physics to discern the fundamental processes that accelerate particles.
Read about how SLAC professor Siegfried Glenzer creates extreme conditions like those in the cores of planets and studies nuclear fusion.
Join us for five days of ultrafast science from April 17 to 21.
Computer simulations and lab experiments help researchers understand the violent universe and could potentially lead to new technologies that benefit humankind.
The 2010 experiment marked a significant step forward in understanding extreme states of matter at the hearts of stars, planets and nuclear fusion reactions.
A 200-terawatt laser at SLAC will synchronize with X-ray laser pulses to precisely measure more extreme temperatures and pressures in exotic forms of matter.