Evaluation of Electrostatic Confinement Fusion as an Energy Source

Jaykob Maser

Department

Physics

Major

Physics

Research Advisor

Story, J. Greg

Advisor's Department

Physics

Funding Source

Department of Physics

Abstract

Fusion is highly sought after for its ability to efficiently provide abundant energy with minimal waste. There are currently multiple competing designs, the most successful of which have operated by the confinement of high energy plasma via electro-magnetic means. In this project an Inertial Electrostatic Confinement (IEC) fusion device was constructed to gauge its potential to achieve a net positive energy yield. The characteristics of the plasma were measured prior to an investigation of the fusion properties via Langmuir Probe and spectroscopic techniques. Data on neutron emissivity for several operation regimes of the IEC device were examined including; variations of the acceleration grid, reversed polarity (false anode), and resonant wave modes.

Biography

Jaykob Maser is currently studying physics at the Missouri University of Science and Technology. He holds an associate's degree in math and science from Northwest Missouri State University. Jaykob also works as a teaching assistant in the physics department, overseeing a section of the Kinematics and Energy Lab. He will be going to graduate school soon, seeking a master's degree at Missouri S&T before proceeding to work on a doctorate elsewhere. His field of interests are plasma and nuclear physics.

Research Category

Sciences

Presentation Type

Poster Presentation

Document Type

Poster

Location

Upper Atrium/Hall

Presentation Date

16 Apr 2014, 9:00 am - 11:45 am

Comments

Joint project with Brock Ebert, and Sheldon Harper

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Apr 16th, 9:00 AM Apr 16th, 11:45 AM

Evaluation of Electrostatic Confinement Fusion as an Energy Source

Upper Atrium/Hall

Fusion is highly sought after for its ability to efficiently provide abundant energy with minimal waste. There are currently multiple competing designs, the most successful of which have operated by the confinement of high energy plasma via electro-magnetic means. In this project an Inertial Electrostatic Confinement (IEC) fusion device was constructed to gauge its potential to achieve a net positive energy yield. The characteristics of the plasma were measured prior to an investigation of the fusion properties via Langmuir Probe and spectroscopic techniques. Data on neutron emissivity for several operation regimes of the IEC device were examined including; variations of the acceleration grid, reversed polarity (false anode), and resonant wave modes.