GEM3k: Architecture and Design of a Novel 3rd Generation High Channel Density Soft X-Ray Diagnostic System Towards Commercial Fusion Power Plants.
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| Title: | GEM3k: Architecture and Design of a Novel 3rd Generation High Channel Density Soft X-Ray Diagnostic System Towards Commercial Fusion Power Plants. |
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| Authors: | Wojeński, Andrzej1 (AUTHOR) andrzej.wojenski@pw.edu.pl, Kasprowicz, Grzegorz1,2 (AUTHOR), Chernyshova, Maryna1,2 (AUTHOR) |
| Source: | Energies (19961073). Feb2026, Vol. 19 Issue 4, p918. 41p. |
| Subject Terms: | *Soft X rays, *Plasma diagnostics, *Real-time computing, *Fusion reactors, *Field programmable gate arrays, *Particle detectors, *Plasma stability |
| Abstract: | Achieving reliable, grid-scale electricity generation from nuclear fusion, as envisioned by the DEMOnstration Fusion Power Plant (DEMO) and future commercial reactors, requires unprecedented plasma stability and long-term control. This operational goal is fundamentally challenged by, among others, the dynamic nature of the high temperature plasma and the need to monitor high-Z impurities, such as tungsten, which can severely compromise energy confinement, resulting in discharge disruption and damage to internal reactor walls. Real-time Soft X-ray (SXR) diagnostic systems are therefore an integral and critical component of fusion power plant infrastructure, providing essential temporal and spatial resolution data on these fast-evolving phenomena. To address the severe demands imposed by the extreme operating environment of future fusion reactors, such as DEMO (including intense neutron and gamma fluxes), this work details a current stage in the long-term development of an advanced and robust diagnostic system engineered specifically for technological preparation and future application in these high-fluence environments. This paper presents the third generation of the SXR measurement system, GEM3k, based on Gas Electron Multiplier (GEM) technology. This novel diagnostic utilizes a Field Programmable Gate Array (FPGA)-based architecture, specifically designed for the high-rate acquisition of energy- and spatially resolved plasma radiation distributions. The GEM3k design exploits the inherent radiation hardness of GEM detectors, positioning them as robust sensor units for monitoring plasma dynamics and impurity emissions in future fusion environments. The system readout comprises approximately 34,000 individual pixels mapped to nearly 3000 measurement channels in an XYUV coordinate configuration. This layout enables submillimeter spatial resolution simultaneously with a time resolution better than 10 ms. Addressing the engineering challenges of such a complex high-density readout, this work details the comprehensive design of the GEM3k system, focusing on its architecture, electronics, performance estimations, and data distribution strategies. By enabling precise tracking of impurities and fast plasma behavior, the GEM3k system contributes to the stable, high-gain operation required for future fusion reactors. This directly supports the development of sustainable fusion energy and its eventual integration into modern electricity grids. Furthermore, the planned enhancement to a real-time operating mode could pave a way for a next-generation system for direct integration into reactor control loops. Currently in the prototype phase with initial hardware tests completed, the GEM3k design leverages our extensive experience with diagnostics developed for the JET and WEST tokamaks. [ABSTRACT FROM AUTHOR] |
| Database: | Energy & Power Source |
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