Inertia
Overview
We are seeking an
Experimental Physicist
to investigate and advance Inertial Fusion Energy (IFE) relevant physics, including the effects of material defects on implosion performance and the radiation drive behavior of alternative hohlraum materials. This role bridges material science, plasma physics, and diagnostic analysis to improve predictive models and guide target fabrication tolerances.
Primary Responsibilities
Design and execute experiments to measure explore key physics and survival properties for Inertia’s target design
Work closely with simulation teams to validate models and identify performance limits.
Analyze experimental data from laser-plasma experiments
Develop new metrology and diagnostic methods to characterize material and target quality.
Document results and contribute to scientific publications and internal reports.
Qualifications
Required:
PhD in Physics, Materials Science, or related discipline and 3-5 years experience in the field.
Experience with high-energy-density physics experiments or laser–plasma interaction studies.
Proficiency in data analysis and modeling tools (e.g., Python, MATLAB, or equivalent).
Preferred:
Experience working with large-scale laser facilities (NIF, OMEGA, etc.).
Knowledge of target fabrication processes and defect characterization.
Strong communication skills for multidisciplinary collaboration.
Salary & Benefits We offer an excellent benefits program, including Medical, Dental, and Vision plans, company-paid holidays, matching 401k, and more!
About Inertia Inertia is taking the most direct, scientifically-proven path to commercializing fusion, leveraging the only successful achievement of fusion ignition, using a process that was pioneered at the U.S. Department of Energy’s (DOE) Lawrence Livermore National Laboratory (LLNL). With groundbreaking innovation, transformative technology, and multi-year investment, Inertia is committed to commercializing fusion energy in the next decade.
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Experimental Physicist
to investigate and advance Inertial Fusion Energy (IFE) relevant physics, including the effects of material defects on implosion performance and the radiation drive behavior of alternative hohlraum materials. This role bridges material science, plasma physics, and diagnostic analysis to improve predictive models and guide target fabrication tolerances.
Primary Responsibilities
Design and execute experiments to measure explore key physics and survival properties for Inertia’s target design
Work closely with simulation teams to validate models and identify performance limits.
Analyze experimental data from laser-plasma experiments
Develop new metrology and diagnostic methods to characterize material and target quality.
Document results and contribute to scientific publications and internal reports.
Qualifications
Required:
PhD in Physics, Materials Science, or related discipline and 3-5 years experience in the field.
Experience with high-energy-density physics experiments or laser–plasma interaction studies.
Proficiency in data analysis and modeling tools (e.g., Python, MATLAB, or equivalent).
Preferred:
Experience working with large-scale laser facilities (NIF, OMEGA, etc.).
Knowledge of target fabrication processes and defect characterization.
Strong communication skills for multidisciplinary collaboration.
Salary & Benefits We offer an excellent benefits program, including Medical, Dental, and Vision plans, company-paid holidays, matching 401k, and more!
About Inertia Inertia is taking the most direct, scientifically-proven path to commercializing fusion, leveraging the only successful achievement of fusion ignition, using a process that was pioneered at the U.S. Department of Energy’s (DOE) Lawrence Livermore National Laboratory (LLNL). With groundbreaking innovation, transformative technology, and multi-year investment, Inertia is committed to commercializing fusion energy in the next decade.
#J-18808-Ljbffr