Fusion research in the United States is sponsored by the Department of Energy's Office of Fusion Energy Sciences (OFES). The OFES sponsors a wide range of programs to advance fusion science, fusion technology, and basic plasma science. Most experimental devices in the US fusion program are constructed using conventional technologies; however, a small portion of the fusion research program is directed towards large scale commercial power generation, which typically relies on superconductor technology to facilitate steady-state operation with high fusion power gain, Q. The superconductor portion of the US fusion research program is limited to a small number of laboratories including the Plasma Science and Fusion Center at MIT, Lawrence L...
This paper gives a review of the application of superconductivity to nuclear fusion magnets. For eac...
With the first tokamak designed for full nuclear operation now well into final assembly (ITER), and ...
The field of superconductivity is rich in history – more than 100 years – yet still at the forefront...
Abstract—Future superconducting magnets for fusion applications require improvements in materials an...
This article will explain the possibilities of nuclear fusion based on the functionality of supercon...
Considerable progress has been achieved during the last few decades in the various fields of applied...
Both the new high temperature superconductors (HTS) and the low temperature superconductors (LTS) ar...
Fusion nuclear technology (FNT) research in the United States encompasses many activities and requir...
In FY97, the General Atomics (GA) Fusion Group made significant contributions to the technology need...
Magnetic fusion reactors need a superconducting coil system with the huge magnetic energy of approxi...
The Fusion Program of Oak Ridge National Laboratory (ORNL) carries out research in most areas of mag...
The Oak Ridge National Laboratory (ORNL) Superconducting Technology Program is conducted as part of ...
Supporting research activities continued to provide the technical basis for future mirror-confinemen...
Mirror experiments have led the way in applying superconductivity to fusion research because of uniq...
With the first tokamak designed for full nuclear operation now well into final assembly (ITER), and ...
This paper gives a review of the application of superconductivity to nuclear fusion magnets. For eac...
With the first tokamak designed for full nuclear operation now well into final assembly (ITER), and ...
The field of superconductivity is rich in history – more than 100 years – yet still at the forefront...
Abstract—Future superconducting magnets for fusion applications require improvements in materials an...
This article will explain the possibilities of nuclear fusion based on the functionality of supercon...
Considerable progress has been achieved during the last few decades in the various fields of applied...
Both the new high temperature superconductors (HTS) and the low temperature superconductors (LTS) ar...
Fusion nuclear technology (FNT) research in the United States encompasses many activities and requir...
In FY97, the General Atomics (GA) Fusion Group made significant contributions to the technology need...
Magnetic fusion reactors need a superconducting coil system with the huge magnetic energy of approxi...
The Fusion Program of Oak Ridge National Laboratory (ORNL) carries out research in most areas of mag...
The Oak Ridge National Laboratory (ORNL) Superconducting Technology Program is conducted as part of ...
Supporting research activities continued to provide the technical basis for future mirror-confinemen...
Mirror experiments have led the way in applying superconductivity to fusion research because of uniq...
With the first tokamak designed for full nuclear operation now well into final assembly (ITER), and ...
This paper gives a review of the application of superconductivity to nuclear fusion magnets. For eac...
With the first tokamak designed for full nuclear operation now well into final assembly (ITER), and ...
The field of superconductivity is rich in history – more than 100 years – yet still at the forefront...