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solps simulation and synthetic diagnostic results matlab files  (MathWorks Inc)


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    MathWorks Inc solps simulation and synthetic diagnostic results matlab files
    <t>Synthetic</t> D 2 Fulcher emission from <t>SOLPS-ITER</t> simulations for the Super-X (SXD) ( a , blue), Elongated (ED) ( b , green) and Conventional Divertors (CD ( c , red), overlaid with 5 eV contours (dashed lines) and the separatrix (solid line). d – f Experimentally measured D 2 Fulcher band emission (595-605 nm) for a strike point scan with magnetic equilibrium shown, moving from CD to SXD at constant density and power, obtained through inverting Multi-Wavelength-Imaging (MWI) imaging data for # 46895 . g – i 1D ion sources and sinks (ionisation - magenta, Molecular Activated Recombination (MAR) ion sink - magenta, Electron-Ion Recombination (EIR) ion sink - cyan), obtained from spectroscopic analysis integrated along the spectroscopic lines of sight (Fig. b) (part. m −2 s −1 ), compared against synthetic diagnostic results from SOLPS-ITER simulations (dotted lines). For the SXD ( g ) two SOLPS-ITER simulation results are shown: one with default rates and one with corrected molecular charge exchange ( \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${{{{\rm{D}}}}}_{{{{\rm{2}}}}}+{{{{\rm{D}}}}}^{+}\to {{{{{\rm{D}}}}}_{{{{\rm{2}}}}}}^{+}+{{{\rm{D}}}}$$\end{document} D 2 + D + → D 2 + + D ) rates (‘Sim. Corr. Rate’), obtained from , which increases MAR. To guide the eye, a shaded magenta vertical line has been added at a radius of 0.95 m and a black arrow has been added at the strike point location ( a – i ). The experimental results in ( g , h , i ) are derived from a probabilistic sample obtained from a Bayesian spectroscopic analysis, showing the median (solid lines) and the 68% equal-tailed confidence interval (shaded region). See Methods section for more information about the analysis and uncertainty propagation.
    Solps Simulation And Synthetic Diagnostic Results Matlab Files, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/solps simulation and synthetic diagnostic results matlab files/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    solps simulation and synthetic diagnostic results matlab files - by Bioz Stars, 2026-04
    90/100 stars

    Images

    1) Product Images from "Divertor shaping with neutral baffling as a solution to the tokamak power exhaust challenge"

    Article Title: Divertor shaping with neutral baffling as a solution to the tokamak power exhaust challenge

    Journal: Communications Physics

    doi: 10.1038/s42005-025-02121-1

    Synthetic D 2 Fulcher emission from SOLPS-ITER simulations for the Super-X (SXD) ( a , blue), Elongated (ED) ( b , green) and Conventional Divertors (CD ( c , red), overlaid with 5 eV contours (dashed lines) and the separatrix (solid line). d – f Experimentally measured D 2 Fulcher band emission (595-605 nm) for a strike point scan with magnetic equilibrium shown, moving from CD to SXD at constant density and power, obtained through inverting Multi-Wavelength-Imaging (MWI) imaging data for # 46895 . g – i 1D ion sources and sinks (ionisation - magenta, Molecular Activated Recombination (MAR) ion sink - magenta, Electron-Ion Recombination (EIR) ion sink - cyan), obtained from spectroscopic analysis integrated along the spectroscopic lines of sight (Fig. b) (part. m −2 s −1 ), compared against synthetic diagnostic results from SOLPS-ITER simulations (dotted lines). For the SXD ( g ) two SOLPS-ITER simulation results are shown: one with default rates and one with corrected molecular charge exchange ( \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${{{{\rm{D}}}}}_{{{{\rm{2}}}}}+{{{{\rm{D}}}}}^{+}\to {{{{{\rm{D}}}}}_{{{{\rm{2}}}}}}^{+}+{{{\rm{D}}}}$$\end{document} D 2 + D + → D 2 + + D ) rates (‘Sim. Corr. Rate’), obtained from , which increases MAR. To guide the eye, a shaded magenta vertical line has been added at a radius of 0.95 m and a black arrow has been added at the strike point location ( a – i ). The experimental results in ( g , h , i ) are derived from a probabilistic sample obtained from a Bayesian spectroscopic analysis, showing the median (solid lines) and the 68% equal-tailed confidence interval (shaded region). See Methods section for more information about the analysis and uncertainty propagation.
    Figure Legend Snippet: Synthetic D 2 Fulcher emission from SOLPS-ITER simulations for the Super-X (SXD) ( a , blue), Elongated (ED) ( b , green) and Conventional Divertors (CD ( c , red), overlaid with 5 eV contours (dashed lines) and the separatrix (solid line). d – f Experimentally measured D 2 Fulcher band emission (595-605 nm) for a strike point scan with magnetic equilibrium shown, moving from CD to SXD at constant density and power, obtained through inverting Multi-Wavelength-Imaging (MWI) imaging data for # 46895 . g – i 1D ion sources and sinks (ionisation - magenta, Molecular Activated Recombination (MAR) ion sink - magenta, Electron-Ion Recombination (EIR) ion sink - cyan), obtained from spectroscopic analysis integrated along the spectroscopic lines of sight (Fig. b) (part. m −2 s −1 ), compared against synthetic diagnostic results from SOLPS-ITER simulations (dotted lines). For the SXD ( g ) two SOLPS-ITER simulation results are shown: one with default rates and one with corrected molecular charge exchange ( \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${{{{\rm{D}}}}}_{{{{\rm{2}}}}}+{{{{\rm{D}}}}}^{+}\to {{{{{\rm{D}}}}}_{{{{\rm{2}}}}}}^{+}+{{{\rm{D}}}}$$\end{document} D 2 + D + → D 2 + + D ) rates (‘Sim. Corr. Rate’), obtained from , which increases MAR. To guide the eye, a shaded magenta vertical line has been added at a radius of 0.95 m and a black arrow has been added at the strike point location ( a – i ). The experimental results in ( g , h , i ) are derived from a probabilistic sample obtained from a Bayesian spectroscopic analysis, showing the median (solid lines) and the 68% equal-tailed confidence interval (shaded region). See Methods section for more information about the analysis and uncertainty propagation.

    Techniques Used: Imaging, Diagnostic Assay, Derivative Assay

    a – c 2D ionisation source from SOLPS-ITER simulations (shown in Fig. ) with horizontal lines at z = −1.6 m (pink) and z = 1.07 m (magenta), demarking the edge of the divertor spectroscopy view and X-point, respectively. The fraction of the ion source downstream these limits compared to the total ion source (outer leg only) are noted. d – f Synthetic diagnostic for the D 2 Fulcher emissivity (arbitrary units) obtained from SOLPS-ITER simulations. g – i Measured D 2 Fulcher emissivity (595-605 nm) obtained from combined divertor imaging and X-point imaging inversions. The indicated time and discharges used are shown and are obtained from repeat discharges for the same core density as used in Fig. . A horizontal line at the height of the X-point location is added (magenta). Only emissivities obtained at the same r , z corresponding to the simulation grids are shown. An inversion artefact is present near r = 0.85 m, z = −1.6 m, where there is a gap in coverage between the X-point and divertor imaging systems. Data are shown for the Super-X (SXD, blue, a , d , g ), Elongated (ED, green, b , e , h ) and Conventional (CD, red, c , f , i ) Divertors.
    Figure Legend Snippet: a – c 2D ionisation source from SOLPS-ITER simulations (shown in Fig. ) with horizontal lines at z = −1.6 m (pink) and z = 1.07 m (magenta), demarking the edge of the divertor spectroscopy view and X-point, respectively. The fraction of the ion source downstream these limits compared to the total ion source (outer leg only) are noted. d – f Synthetic diagnostic for the D 2 Fulcher emissivity (arbitrary units) obtained from SOLPS-ITER simulations. g – i Measured D 2 Fulcher emissivity (595-605 nm) obtained from combined divertor imaging and X-point imaging inversions. The indicated time and discharges used are shown and are obtained from repeat discharges for the same core density as used in Fig. . A horizontal line at the height of the X-point location is added (magenta). Only emissivities obtained at the same r , z corresponding to the simulation grids are shown. An inversion artefact is present near r = 0.85 m, z = −1.6 m, where there is a gap in coverage between the X-point and divertor imaging systems. Data are shown for the Super-X (SXD, blue, a , d , g ), Elongated (ED, green, b , e , h ) and Conventional (CD, red, c , f , i ) Divertors.

    Techniques Used: Spectroscopy, Diagnostic Assay, Imaging



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    solps simulation and synthetic diagnostic results matlab files  (MathWorks Inc)
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    MathWorks Inc solps simulation and synthetic diagnostic results matlab files
    <t>Synthetic</t> D 2 Fulcher emission from <t>SOLPS-ITER</t> simulations for the Super-X (SXD) ( a , blue), Elongated (ED) ( b , green) and Conventional Divertors (CD ( c , red), overlaid with 5 eV contours (dashed lines) and the separatrix (solid line). d – f Experimentally measured D 2 Fulcher band emission (595-605 nm) for a strike point scan with magnetic equilibrium shown, moving from CD to SXD at constant density and power, obtained through inverting Multi-Wavelength-Imaging (MWI) imaging data for # 46895 . g – i 1D ion sources and sinks (ionisation - magenta, Molecular Activated Recombination (MAR) ion sink - magenta, Electron-Ion Recombination (EIR) ion sink - cyan), obtained from spectroscopic analysis integrated along the spectroscopic lines of sight (Fig. b) (part. m −2 s −1 ), compared against synthetic diagnostic results from SOLPS-ITER simulations (dotted lines). For the SXD ( g ) two SOLPS-ITER simulation results are shown: one with default rates and one with corrected molecular charge exchange ( \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${{{{\rm{D}}}}}_{{{{\rm{2}}}}}+{{{{\rm{D}}}}}^{+}\to {{{{{\rm{D}}}}}_{{{{\rm{2}}}}}}^{+}+{{{\rm{D}}}}$$\end{document} D 2 + D + → D 2 + + D ) rates (‘Sim. Corr. Rate’), obtained from , which increases MAR. To guide the eye, a shaded magenta vertical line has been added at a radius of 0.95 m and a black arrow has been added at the strike point location ( a – i ). The experimental results in ( g , h , i ) are derived from a probabilistic sample obtained from a Bayesian spectroscopic analysis, showing the median (solid lines) and the 68% equal-tailed confidence interval (shaded region). See Methods section for more information about the analysis and uncertainty propagation.
    Solps Simulation And Synthetic Diagnostic Results Matlab Files, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/solps simulation and synthetic diagnostic results matlab files/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    solps simulation and synthetic diagnostic results matlab files - by Bioz Stars, 2026-04
    90/100 stars
    		  Buy from Supplier

    Image Search Results


    Synthetic D 2 Fulcher emission from SOLPS-ITER simulations for the Super-X (SXD) ( a , blue), Elongated (ED) ( b , green) and Conventional Divertors (CD ( c , red), overlaid with 5 eV contours (dashed lines) and the separatrix (solid line). d – f Experimentally measured D 2 Fulcher band emission (595-605 nm) for a strike point scan with magnetic equilibrium shown, moving from CD to SXD at constant density and power, obtained through inverting Multi-Wavelength-Imaging (MWI) imaging data for # 46895 . g – i 1D ion sources and sinks (ionisation - magenta, Molecular Activated Recombination (MAR) ion sink - magenta, Electron-Ion Recombination (EIR) ion sink - cyan), obtained from spectroscopic analysis integrated along the spectroscopic lines of sight (Fig. b) (part. m −2 s −1 ), compared against synthetic diagnostic results from SOLPS-ITER simulations (dotted lines). For the SXD ( g ) two SOLPS-ITER simulation results are shown: one with default rates and one with corrected molecular charge exchange ( \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${{{{\rm{D}}}}}_{{{{\rm{2}}}}}+{{{{\rm{D}}}}}^{+}\to {{{{{\rm{D}}}}}_{{{{\rm{2}}}}}}^{+}+{{{\rm{D}}}}$$\end{document} D 2 + D + → D 2 + + D ) rates (‘Sim. Corr. Rate’), obtained from , which increases MAR. To guide the eye, a shaded magenta vertical line has been added at a radius of 0.95 m and a black arrow has been added at the strike point location ( a – i ). The experimental results in ( g , h , i ) are derived from a probabilistic sample obtained from a Bayesian spectroscopic analysis, showing the median (solid lines) and the 68% equal-tailed confidence interval (shaded region). See Methods section for more information about the analysis and uncertainty propagation.

    Journal: Communications Physics

    Article Title: Divertor shaping with neutral baffling as a solution to the tokamak power exhaust challenge

    doi: 10.1038/s42005-025-02121-1

    Figure Lengend Snippet: Synthetic D 2 Fulcher emission from SOLPS-ITER simulations for the Super-X (SXD) ( a , blue), Elongated (ED) ( b , green) and Conventional Divertors (CD ( c , red), overlaid with 5 eV contours (dashed lines) and the separatrix (solid line). d – f Experimentally measured D 2 Fulcher band emission (595-605 nm) for a strike point scan with magnetic equilibrium shown, moving from CD to SXD at constant density and power, obtained through inverting Multi-Wavelength-Imaging (MWI) imaging data for # 46895 . g – i 1D ion sources and sinks (ionisation - magenta, Molecular Activated Recombination (MAR) ion sink - magenta, Electron-Ion Recombination (EIR) ion sink - cyan), obtained from spectroscopic analysis integrated along the spectroscopic lines of sight (Fig. b) (part. m −2 s −1 ), compared against synthetic diagnostic results from SOLPS-ITER simulations (dotted lines). For the SXD ( g ) two SOLPS-ITER simulation results are shown: one with default rates and one with corrected molecular charge exchange ( \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${{{{\rm{D}}}}}_{{{{\rm{2}}}}}+{{{{\rm{D}}}}}^{+}\to {{{{{\rm{D}}}}}_{{{{\rm{2}}}}}}^{+}+{{{\rm{D}}}}$$\end{document} D 2 + D + → D 2 + + D ) rates (‘Sim. Corr. Rate’), obtained from , which increases MAR. To guide the eye, a shaded magenta vertical line has been added at a radius of 0.95 m and a black arrow has been added at the strike point location ( a – i ). The experimental results in ( g , h , i ) are derived from a probabilistic sample obtained from a Bayesian spectroscopic analysis, showing the median (solid lines) and the 68% equal-tailed confidence interval (shaded region). See Methods section for more information about the analysis and uncertainty propagation.

    Article Snippet: The data is provided in a zip file containing folders of: 1) general data on discharge parameters (Numpy files) (Fig. ); 2) spectroscopic analysis results (Numpy files) (Figs. , , ); 3) imaging (MWI) inversions (Numpy files) (Fig. ); 4) Thomson scattering data (Matlab files) (Fig. ); 5) SOLPS simulation and synthetic diagnostic results (Matlab files) (Fig. ); 6) predictions from the DLS model (Table ).

    Techniques: Imaging, Diagnostic Assay, Derivative Assay

    a – c 2D ionisation source from SOLPS-ITER simulations (shown in Fig. ) with horizontal lines at z = −1.6 m (pink) and z = 1.07 m (magenta), demarking the edge of the divertor spectroscopy view and X-point, respectively. The fraction of the ion source downstream these limits compared to the total ion source (outer leg only) are noted. d – f Synthetic diagnostic for the D 2 Fulcher emissivity (arbitrary units) obtained from SOLPS-ITER simulations. g – i Measured D 2 Fulcher emissivity (595-605 nm) obtained from combined divertor imaging and X-point imaging inversions. The indicated time and discharges used are shown and are obtained from repeat discharges for the same core density as used in Fig. . A horizontal line at the height of the X-point location is added (magenta). Only emissivities obtained at the same r , z corresponding to the simulation grids are shown. An inversion artefact is present near r = 0.85 m, z = −1.6 m, where there is a gap in coverage between the X-point and divertor imaging systems. Data are shown for the Super-X (SXD, blue, a , d , g ), Elongated (ED, green, b , e , h ) and Conventional (CD, red, c , f , i ) Divertors.

    Journal: Communications Physics

    Article Title: Divertor shaping with neutral baffling as a solution to the tokamak power exhaust challenge

    doi: 10.1038/s42005-025-02121-1

    Figure Lengend Snippet: a – c 2D ionisation source from SOLPS-ITER simulations (shown in Fig. ) with horizontal lines at z = −1.6 m (pink) and z = 1.07 m (magenta), demarking the edge of the divertor spectroscopy view and X-point, respectively. The fraction of the ion source downstream these limits compared to the total ion source (outer leg only) are noted. d – f Synthetic diagnostic for the D 2 Fulcher emissivity (arbitrary units) obtained from SOLPS-ITER simulations. g – i Measured D 2 Fulcher emissivity (595-605 nm) obtained from combined divertor imaging and X-point imaging inversions. The indicated time and discharges used are shown and are obtained from repeat discharges for the same core density as used in Fig. . A horizontal line at the height of the X-point location is added (magenta). Only emissivities obtained at the same r , z corresponding to the simulation grids are shown. An inversion artefact is present near r = 0.85 m, z = −1.6 m, where there is a gap in coverage between the X-point and divertor imaging systems. Data are shown for the Super-X (SXD, blue, a , d , g ), Elongated (ED, green, b , e , h ) and Conventional (CD, red, c , f , i ) Divertors.

    Article Snippet: The data is provided in a zip file containing folders of: 1) general data on discharge parameters (Numpy files) (Fig. ); 2) spectroscopic analysis results (Numpy files) (Figs. , , ); 3) imaging (MWI) inversions (Numpy files) (Fig. ); 4) Thomson scattering data (Matlab files) (Fig. ); 5) SOLPS simulation and synthetic diagnostic results (Matlab files) (Fig. ); 6) predictions from the DLS model (Table ).

    Techniques: Spectroscopy, Diagnostic Assay, Imaging