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| Main Authors: | , , , , , , , , , , |
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| Format: | Preprint |
| Published: |
2024
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2409.04278 |
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| _version_ | 1866929554827771904 |
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| author | Moscheni, Matteo Maartensson, Erik Robinson, Matthew Marsden, Chris Rengle, Adrian Scarabosio, Andrea Bunting, Patrick Gray, Travis Kelly Janhunen, Salomon Vekshina, Elena Zhang, Xin |
| author_facet | Moscheni, Matteo Maartensson, Erik Robinson, Matthew Marsden, Chris Rengle, Adrian Scarabosio, Andrea Bunting, Patrick Gray, Travis Kelly Janhunen, Salomon Vekshina, Elena Zhang, Xin |
| contents | Infra-red (IR) thermography is an essential diagnostic tool for understanding the edge plasma behavior in fusion devices. In this work, we present a new in-house numerical tool, Functional Analysis of Heat Flux (FAHF), for IR thermographic inversion on Tokamak Energy's spherical tokamak (ST40). FAHF, written in Python, is designed for multi-2D thermographic inversions by solving the heat conduction equation within the divertor tiles using the finite difference method, and an explicit time stepping scheme. Utilising IR camera data with the highest available effective spatial resolution, FAHF calculates the plasma perpendicular heat flux density on the divertor tile surfaces -- a crucial quantity for edge plasma analysis. The tool's internal numerics is first verified through formal time and space convergence analyses, and further corroborated by an energy balance assessment. Although FAHF demonstrates significant sensitivity to user-selected spatial resolution, precise heat flux values are recoverable by ensuring a sufficiently high resolution. Implications for the optimal resolution of both the code and the diagnostic system are discussed. Finally, FAHF's model and geometry simplifications are confirmed to be accurate within 10%, based on comparison with COMSOL Multiphysics simulations. As such, FAHF is proven to be a precise and accurate tool for IR thermographic inversions in ST40. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2409_04278 |
| institution | arXiv |
| publishDate | 2024 |
| record_format | arxiv |
| spellingShingle | Infra-red thermographic inversion in ST40 Moscheni, Matteo Maartensson, Erik Robinson, Matthew Marsden, Chris Rengle, Adrian Scarabosio, Andrea Bunting, Patrick Gray, Travis Kelly Janhunen, Salomon Vekshina, Elena Zhang, Xin Plasma Physics Infra-red (IR) thermography is an essential diagnostic tool for understanding the edge plasma behavior in fusion devices. In this work, we present a new in-house numerical tool, Functional Analysis of Heat Flux (FAHF), for IR thermographic inversion on Tokamak Energy's spherical tokamak (ST40). FAHF, written in Python, is designed for multi-2D thermographic inversions by solving the heat conduction equation within the divertor tiles using the finite difference method, and an explicit time stepping scheme. Utilising IR camera data with the highest available effective spatial resolution, FAHF calculates the plasma perpendicular heat flux density on the divertor tile surfaces -- a crucial quantity for edge plasma analysis. The tool's internal numerics is first verified through formal time and space convergence analyses, and further corroborated by an energy balance assessment. Although FAHF demonstrates significant sensitivity to user-selected spatial resolution, precise heat flux values are recoverable by ensuring a sufficiently high resolution. Implications for the optimal resolution of both the code and the diagnostic system are discussed. Finally, FAHF's model and geometry simplifications are confirmed to be accurate within 10%, based on comparison with COMSOL Multiphysics simulations. As such, FAHF is proven to be a precise and accurate tool for IR thermographic inversions in ST40. |
| title | Infra-red thermographic inversion in ST40 |
| topic | Plasma Physics |
| url | https://arxiv.org/abs/2409.04278 |