A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Modeling input to the ITER glow discharge boronization system design
The ITER re-baseline proposes changing the first wall material from beryllium to tungsten and incorporating a boronization system to mitigate plasma operation risks associated with tungsten. This system aims to deposit a 50 nm boron coating on plasma facing surfaces by fuelling diborane with a carrier gas (He, H2, or D2) in a glow discharge, based on the extensive experience from present devices. This paper analyzes the optimal number and distribution of anodes and gas injection locations for achieving a uniform boron coating in ITER. Using Monte Carlo simulations of diborane molecules in the ITER glow discharge plasma, the study examines the spatial distribution of diborane ionization and dissociation reactions, for different anode and gas injection configurations, neutral pressure, and hydrogen versus helium carrier gas concentration. The glow discharge plasma backgrounds are obtained by adapting an existing axisymmetric glow model to simulate helium–hydrogen gas mixtures. The simulation results, initially conducted with a maximum of 2 anodes, are scaled to represent a realistic anode configuration for the ITER equatorial plane. Key findings include that a low hydrogen content in helium, achieved with 5 % diborane in the carrier gas, and a low total pressure yields the best uniform boron deposition. However, thinner layers are expected where ports cannot accommodate additional anodes. Uniform gas injection points, including at the high field side, and separation of gas injection points from anodes are crucial for uniform coatings. These modeling efforts support the design of the ITER boronization system and justify expanding the ITER GDC hardware to include more anodes and gas feed points. Despite the widespread use of boronization in modern tokamaks, boron layer uniformity and its impact on plasma performance remains under-researched, highlighting the need for dedicated experiments and model benchmarking against results from current devices.
Modeling input to the ITER glow discharge boronization system design
The ITER re-baseline proposes changing the first wall material from beryllium to tungsten and incorporating a boronization system to mitigate plasma operation risks associated with tungsten. This system aims to deposit a 50 nm boron coating on plasma facing surfaces by fuelling diborane with a carrier gas (He, H2, or D2) in a glow discharge, based on the extensive experience from present devices. This paper analyzes the optimal number and distribution of anodes and gas injection locations for achieving a uniform boron coating in ITER. Using Monte Carlo simulations of diborane molecules in the ITER glow discharge plasma, the study examines the spatial distribution of diborane ionization and dissociation reactions, for different anode and gas injection configurations, neutral pressure, and hydrogen versus helium carrier gas concentration. The glow discharge plasma backgrounds are obtained by adapting an existing axisymmetric glow model to simulate helium–hydrogen gas mixtures. The simulation results, initially conducted with a maximum of 2 anodes, are scaled to represent a realistic anode configuration for the ITER equatorial plane. Key findings include that a low hydrogen content in helium, achieved with 5 % diborane in the carrier gas, and a low total pressure yields the best uniform boron deposition. However, thinner layers are expected where ports cannot accommodate additional anodes. Uniform gas injection points, including at the high field side, and separation of gas injection points from anodes are crucial for uniform coatings. These modeling efforts support the design of the ITER boronization system and justify expanding the ITER GDC hardware to include more anodes and gas feed points. Despite the widespread use of boronization in modern tokamaks, boron layer uniformity and its impact on plasma performance remains under-researched, highlighting the need for dedicated experiments and model benchmarking against results from current devices.
Modeling input to the ITER glow discharge boronization system design
T. Wauters (author) / G.J.M. Hagelaar (author) / R.A. Pitts (author)
2025
Article (Journal)
Electronic Resource
Unknown
Metadata by DOAJ is licensed under CC BY-SA 1.0
Glow Discharge Boronization and Real-Time Boronization Using an Impurity Powder Dropper in LHD
| DOAJ | 2025
Glow Discharge Boronization and Real-Time Boronization Using an Impurity Powder Dropper in LHD
| Elsevier | 2025
Full W ITER: Assessment of expected W erosion and implications of boronization on fuel retention
| Elsevier | 2024
Full W ITER: Assessment of expected W erosion and implications of boronization on fuel retention
| DOAJ | 2024