Company Filing History:
Years Active: 2018-2023
Title: Max Tabak: Innovator in Inertial Confinement Fusion
Introduction
Max Tabak is a prominent inventor based in Livermore, California. He has made significant contributions to the field of inertial confinement fusion, holding a total of 3 patents. His work focuses on enhancing the conditions required for ignition in fusion targets, which is crucial for advancing energy production through fusion technology.
Latest Patents
One of Max Tabak's latest patents involves the use of a hohlraum as a single turn solenoid to generate a seed magnetic field for inertial confinement fusion. This innovation applies axial seed magnetic fields in the range of 20-100 T, which can compress to greater than 10,000 T (100 MG) under typical National Ignition Facility (NIF) implosion conditions. The implications of this technology are profound, as it may significantly relax the conditions required for ignition and propagating burn in NIF ignition targets that are affected by hydrodynamic instabilities. The magnetic fields generated can facilitate the recovery of ignition in submarginal NIF targets, enable ignition in redesigned cryogenic layered solid-DT targets, and improve adverse hohlraum plasma conditions during laser drive and capsule compression.
Career Highlights
Max Tabak is currently employed at Lawrence Livermore National Security, LLC, where he continues to push the boundaries of fusion research. His innovative approaches have garnered attention and respect within the scientific community, contributing to advancements in energy technology.
Collaborations
Throughout his career, Max has collaborated with notable colleagues, including Lindsay John Perkins and Jim H Hammer. These partnerships have fostered a collaborative environment that enhances the research and development of fusion technologies.
Conclusion
Max Tabak's contributions to inertial confinement fusion represent a significant step forward in the quest for sustainable energy solutions. His innovative patents and collaborative efforts continue to shape the future of fusion research.