Pulsed Power

Pulsed-Power Science and Technology

About Pulsed Power

Our scientists and engineers use Pulsed Power to concentrate electrical energy in space and time.

Key Research Facilities

Our facilities include the Z accelerator, which produces powerful soft x rays and magnetic fields for research in high energy density physics, the Saturn x-ray source, and the High-Energy Radiation Megavolt Electron Source (HERMES) III for gamma rays.

Internship Opportunities

Undergraduate and graduate students are provided with the opportunity to gain experience working at a world class pulsed power facility through the SEERI Program.
  • Advanced Pulsed Power Concepts

    Experiments conducted on Sandia’s Z Machine create the extreme radiation, pressure and temperatures produced in a nuclear blast.  Technical experts apply theoretical, computational and diagnostic tools to analyze results from Z and other experimental platforms.  The results also create opportunities for new science and engineering discoveries, from understanding materials behavior and providing insights into astrophysics and planetary science, to one day achieving the elusive goal of creating fusion energy in the laboratory.
  • Planetary Research

    The bright lights of Venus, Mars, and Jupiter have captured the imagination of people for eons. Scientists at Sandia National Laboratories use the Z machine to create matter found in conditions at the core of the Earth or the deep interior of Neptune and Jupiter, and measure the properties.
  • Astrophysics

    Sandia’s Z machine provides us with the capability to delve deep into discovery science to study the behavior of matter at extreme conditions.  This contributes to our fundamental understanding of nature and the universe.

  • Inertial Confinement Fusion

    Inertial confinement fusion (ICF) is a method that attempts to initiate nuclear fusion reactions by heating and compressing a fuel target, typically in the form of a pellet that most often contains a mixture of deuterium and tritium. Scientists at Sandia have now shown that a strategy called Magnetized Liner Inertial Fusion (MagLIF) in which a strong magnetic field is embedded in an imploding plasma of deuterium gas, is effective at retaining the heat necessary for fusion.

  • Dynamic Materials

    The science of dynamic material compression is a core capability at Sandia.   Materials are subjected to extreme conditions at Z, a machine which uses massive pulses of electrical power to create huge magnetic fields or to accelerate materials to extremely high velocities of about 50 kilometers (31 miles) per second — far faster than a rifle bullet. Using these means, scientists examine the response of materials at extremely high-energy densities.

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