Fusion reactor design

Seeing more clearly: Revised computer code accurately models an instability in fusion plasmas

Subatomic particles zip around ring-shaped fusion machines known as tokamaks and sometimes merge, releasing large amounts of energy. But these particles — a soup of charged electrons and atomic nuclei, or ions, collectively known as plasma — can sometimes leak out of the magnetic fields that confine them inside tokamaks. The leakage cools the plasma, reducing the efficiency of the fusion reactions and damaging the machine. Now, physicists have confirmed that an updated computer code could help to predict and ultimately prevent such leaks from happening.

Tiny granules can help bring clean and abundant fusion power to Earth

Beryllium, a hard, silvery metal long used in X-ray machines and spacecraft, is finding a new role in the quest to bring the power that drives the sun and stars to Earth. Beryllium is one of the two main materials used for the wall in ITER, a multinational fusion facility under construction in France to demonstrate the practicality of fusion power. Now, physicists from the U.S.

Tiny granules can help bring clean and abundant fusion power to Earth

Beryllium, a hard, silvery metal long used in X-ray machines and spacecraft, is finding a new role in the quest to bring the power that drives the sun and stars to Earth. Beryllium is one of the two main materials used for the wall in ITER, a multinational fusion facility under construction in France to demonstrate the practicality of fusion power. Now, physicists from the U.S.

Ready, set, go: Scientists evaluate a novel technique for firing up the fuel that feeds fusion reactions

To capture and control on Earth the fusion reactions that drive the sun and stars, researchers must first turn room-temperature gas into the hot, charged plasma that fuels the reactions. At the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL), scientists have conducted an analysis that confirms the effectiveness of a novel, non-standard way for starting up plasma in future compact fusion facilities.

Ready, set, go: Scientists evaluate a novel technique for firing up the fuel that feeds fusion reactions

To capture and control on Earth the fusion reactions that drive the sun and stars, researchers must first turn room-temperature gas into the hot, charged plasma that fuels the reactions. At the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL), scientists have conducted an analysis that confirms the effectiveness of a novel, non-standard way for starting up plasma in future compact fusion facilities.

Speeding the development of fusion power to create unlimited energy on Earth

Can tokamak fusion facilities, the most widely used devices for harvesting on Earth the fusion reactions that power the sun and stars, be developed more quickly to produce safe, clean, and virtually limitless energy for generating electricity? Physicist Jon Menard of the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) has examined that question in a detailed look at the concept of a compact tokamak equipped with high temperature superconducting (HTS) magnets.

Speeding the development of fusion power to create unlimited energy on Earth

A look at the pathway to a compact fusion facility equipped with high-temperature superconducting magnets.

PPPL physicist receives funding to research improvements to unique fusion device

Princeton Plasma Physics Laboratory physicist Sam Cohen will receive funding from a U.S. Department of Energy (DOE) award to his collaborator to upgrade and operate his Princeton Field Reversed Configuration device, the PFRC-2. The data produced could allow the design of future devices that might one day be used as a portable generator.

Cohen will receive $700,000 from a $1.25 million award from the Advanced Research Projects Agency-Energy (ARPA-E) to Princeton Fusion Systems, which is working with Cohen on development of the device.

Steve Cowley: The knight who leads the Lab has “the most fun job”

“It’s just all been fun, and this is the most fun job I’ve ever had,” Steve Cowley says of his much-decorated career and his new position, which he assumed July 1, as the seventh director of the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) — the place where the British-born physicist earned his doctorate and that he calls “the most important fusion laboratory in the world.”

Knighted in October

Steve Cowley: The knight who leads the Lab has “the most fun job”

New director brings his life-long vision to "the most important fusion laboratory in the world."

A Collaborative National Center for Fusion & Plasma Research

Fusion reactor design

Seeing more clearly: Revised computer code accurately models an instability in fusion plasmas

Tiny granules can help bring clean and abundant fusion power to Earth

Tiny granules can help bring clean and abundant fusion power to Earth

Ready, set, go: Scientists evaluate a novel technique for firing up the fuel that feeds fusion reactions

Ready, set, go: Scientists evaluate a novel technique for firing up the fuel that feeds fusion reactions

Speeding the development of fusion power to create unlimited energy on Earth

Speeding the development of fusion power to create unlimited energy on Earth

PPPL physicist receives funding to research improvements to unique fusion device

Steve Cowley: The knight who leads the Lab has “the most fun job”

Steve Cowley: The knight who leads the Lab has “the most fun job”

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Robert J Goldston

Dr. Michael C Zarnstorff

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Fusion reactor design

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