What does this research mean for the field?

A fully 3D model incorporating cold collisional physics and a self-consistent geometry-imposed azimuthal spectrum successfully reproduces the experimentally observed transition from edge to core heating in helicon antennas. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This work aims to model the RF power absorption in helicon antennas of the MPEX device using a fully 3D approach.

May 16, 2026

Helicon edge heating in Proto-MPEX: Azimuthally resolved RF modeling

Key Points

This work aims to model the RF power absorption in helicon antennas of the MPEX device using a fully 3D approach.
Developed a 3D model considering cold collisional physics and azimuthal spectrum effects.
Compared modeling results with experimental observations of heating transitions in MPEX.
Successfully reproduced the transition from edge heating to core heating in the helicon antenna.
Demonstrated that 3D modeling captures the complexities of RF power absorption more accurately than previous 2D models.

Abstract

The Material Plasma Exposure eXperiment (MPEX) is a linear device under construction at ORNL. MPEX employs a variety of heating systems, including a helicon antenna, which is the subject of this work. Lacking a resonant absorption mechanism, as tokamaks have, modeling the RF power absorption in such antennas requires detailed consideration of cold collisional physics. Previous modeling of the heating in this antenna was done exclusively in 2D, assuming axisymmetry and a single azimuthal mode number m=1. In this work, we introduce a fully 3D model. By including the full 3D physics, with its self-consistent geometry-imposed azimuthal spectrum, we are able to reproduce the experimentally observed transition from edge heating to core heating.

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Helicon edge heating in Proto-MPEX: Azimuthally resolved RF modeling

Key Points

Abstract

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