William Stromberg
Chief Executive Officer
Over 18 years Developing new materials specifically tailored for fusion applications is crucial. Metallurgists would engage in research and development to create materials with enhanced resistance to radiation damage, improved thermal conductivity, and reduced activation under neutron bombardment. This may involve alloy design, fabrication techniques, and testing methodologies to validate material performance.
About Us
Consulting Extractive Metallurgist
Your expertise in extractive metallurgy would be valuable for developing processing and fabrication techniques optimized for fusion reactor materials.
Our Current Projects
Considerations of Technology Readiness Levels for Fusion Technology Components
Fusion reactions require extremely high temperatures and pressures to initiate and sustain. Technologies related to plasma confinement (such as tokamaks, stellarators, or inertial confinement) and heating systems (like neutral beam injection, radiofrequency heating, and laser heating) must be at a sufficiently high TRL to demonstrate reliable and sustained plasma performance.
Plasma Physics and Technology Aspects of the Deuterium-tritium Fuel Cycle for Fusion Energy
D-T fusion reactions require plasma temperatures of around 100 million degrees Celsius to initiate and sustain the fusion process. Plasma confinement techniques such as magnetic confinement (e.g., tokamaks, stellarators) or inertial confinement (e.g., laser fusion) are employed to achieve these temperatures. Plasma heating methods including neutral beam injection, radiofrequency heating, and laser heating are used to provide the necessary energy to sustain the fusion reaction.
Development and Application of Level 1 Probabilistic Safety Assessment for Nuclear Power Plants
The development of Level 1 PSA involves formulating a methodology for systematically identifying initiating events, modeling their progression, estimating their frequencies, and assessing their consequences.
Uranium Raw Material for the Nuclear Fuel Cycle: Innovation for Sustaining Future Resources and Production
Innovations in geological exploration, such as remote sensing, geophysical surveys, and geochemical analysis, can improve the identification of new uranium deposits and enhance the efficiency of exploration efforts.
