Fusion reactor design

PPPL-led research enhances performance of Germany’s new fusion device

A team of U.S. and German scientists has used a system of large magnetic “trim” coils designed and delivered by the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) to achieve high performance in the latest round of experiments on the Wendelstein 7-X (W7-X) stellarator. The German machine, the world’s largest and most advanced stellarator, is being used to explore the scientific basis for fusion energy and test the suitability of the stellarator design for future fusion power plants.

PPPL-led research enhances performance of Germany’s new fusion device

A team of U.S. and German scientists has used a system of large magnetic “trim” coils designed and delivered by the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) to achieve high performance in the latest round of experiments on the Wendelstein 7-X (W7-X) stellarator. The German machine, the world’s largest and most advanced stellarator, is being used to explore the scientific basis for fusion energy and test the suitability of the stellarator design for future fusion power plants.

Halos look good on angels, but could damage fusion energy devices

Halo currents — electrical currents that flow from the hot, charged plasma that fuels fusion reactions and strike the walls of fusion facilities — could damage the walls of fusion devices like ITER, the international experiment under construction in France to demonstrate the feasibility of fusion power.

Halos look good on angels, but could damage fusion energy devices

Halo currents — electrical currents that flow from the hot, charged plasma that fuels fusion reactions and strike the walls of fusion facilities — could damage the walls of fusion devices like ITER, the international experiment under construction in France to demonstrate the feasibility of fusion power.

Smooth sailing: PPPL develops an integrated approach to understand how to better control instabilities in an international fusion device

A key goal for ITER, the international fusion device under construction in France, will be to produce 10 times more power than goes into it to heat the hot, charged plasma that sustains fusion reactions. Among the steps needed to reach that goal will be controlling instabilities called “neoclassical tearing modes” that can cause magnetic islands to grow in the plasma and shut down those reactions.

Lithium — it’s not just for batteries: The powdered metal can reduce instabilities in fusion plasmas, scientists find

You may be most familiar with the element lithium as an integral component of your smart phone’s battery, but the element also plays a role in the development of clean fusion energy. When used on tungsten surfaces in fusion devices, lithium can reduce periodic instabilities in plasma that can damage the reactor walls, scientists have found.

Lithium — it’s not just for batteries: The powdered metal can reduce instabilities in fusion plasmas

You may be most familiar with the element lithium as an integral component of your smart phone’s battery, but the element also plays a role in the development of clean fusion energy. When used on tungsten surfaces in fusion devices, lithium can reduce periodic instabilities in plasma that can damage the reactor walls, scientists have found.

Ten stories in 2017 you may have missed, plus a bonus

Throughout 2017 researchers at the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) have produced new insights into the science of fusion energy that powers the sun and stars and the physics of plasma, the hot, charged state of matter that consists of electrons and atomic nuclei, or ions, and makes up 99 percent of the visible universe. The research advances the development of fusion as a safe, clean and plentiful source of power, produced in doughnut-shaped facilities called tokamaks, and explores the diverse aspects and applications of plasma.

Ten stories in 2017 you may have missed, plus a bonus

New insights into the science of fusion energy and the physics of plasma from researchers at PPPL.

Innovative design using loops of liquid metal can improve future fusion power plants, scientists say

Researchers led by the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) have proposed an innovative design to improve the ability of future fusion power plants to generate safe, clean and abundant energy in a steady state, or constant, manner. The design uses loops of liquid lithium to clean and recycle the tritium, the radioactive hydrogen isotope that fuels fusion reactions, and to protect the divertor plates from intense exhaust heat from the tokamak that contains the reactions.

A Collaborative National Center for Fusion & Plasma Research

Fusion reactor design

PPPL-led research enhances performance of Germany’s new fusion device

PPPL-led research enhances performance of Germany’s new fusion device

Halos look good on angels, but could damage fusion energy devices

Halos look good on angels, but could damage fusion energy devices

Smooth sailing: PPPL develops an integrated approach to understand how to better control instabilities in an international fusion device

Lithium — it’s not just for batteries: The powdered metal can reduce instabilities in fusion plasmas, scientists find

Lithium — it’s not just for batteries: The powdered metal can reduce instabilities in fusion plasmas

Ten stories in 2017 you may have missed, plus a bonus

Ten stories in 2017 you may have missed, plus a bonus

Innovative design using loops of liquid metal can improve future fusion power plants, scientists say

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Robert J Goldston

Dr. Michael C Zarnstorff

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Fusion reactor design

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