Your search keyword '"Biewer, T. M."' showing total 9 results

1. The CXSFIT spectral fitting code: Past, present and future.

Author

Delabie, E., O'Mullane, M. G., von Hellermann, M., Whiteford, A., Horton, L. D., Zastrow, K. D., Menmuir, S., Litherland-Smith, E., Meigs, A., and Biewer, T. M.

Subjects

CHARGE exchange, COUPLING schemes, PLASMA confinement, STARK effect, SPECTRAL lines

Abstract

Magnetically confined plasma experiments generate a wealth of spectroscopic data. The first step toward extracting physical parameters is to fit a spectral model to the often complex spectra. The CXSFIT (Charge eXchange Spectroscopy FITting) spectral fitting code was originally developed for fitting charge exchange spectra on JET from the late 1980s onward and has been further developed over decades to keep up with the needs of the users. The primary use is to efficiently fit a large number of spectra with many constrained Gaussian spectral lines of which the physical parameters can be coupled in a user-friendly manner. More recent additions to the code include time-dependent couplings between parameters, flexible background subtraction, and a non-linear coupling scheme between fit parameters. The latter was a pre-requisite for implementing Zeeman and motional Stark effect multiplets in the library of spectral features. The ability to save and replay "fit recipes," even when multiple iterations are required, has ensured the traceability of the results and is one of the keys to the longevity and success of the code. The code is also in use on other tokamaks (AUG, ST-40) and to fit data from other spectroscopic diagnostics on JET. In this paper, we document the current capabilities and philosophy behind the structure of the code, including some of the algorithms used to calculate spectral features numerically efficiently. We also provide an outline of how CXSFIT could be transferred into a framework that would be able to meet the spectral fitting requirements of future devices, such as ITER. [ABSTRACT FROM AUTHOR]

Published

2024

2. Conceptual design of a Doppler spectrometer for 102 m/s cross-field flows in tokamak divertors.

Author

Fujii, K., Sano, R., Nakano, T., Ronchi, G., Park, J.-S., Lore, J. D., Shafer, M., and Biewer, T. M.

Abstract

The cross-field transport in the scrape-off-layers (SOLs) and divertors in tokamaks is of a similar size to the poloidal component of the parallel flow, thereby significantly impacting the plasma transport there. However, its direct observation has been challenging because the drift velocity (102–103 m/s) is significantly below the detection limit of conventional diagnostics. To realize cross-field ion flow measurement, a variety of systematic uncertainties in the system must be narrowed down. Here, we develop a conceptual design of the Doppler spectrometry that enables us to measure the impurity flows with 102-m/s accuracy based on an in situ wavelength-calibration technique developed in the astrophysics field, the iodine-cell method. We discuss its properties and applicability. In particular, the scaling relation between wavelength accuracy and various spectroscopic parameters is newly presented, which suggests the high importance of the wavelength resolution of the system. Based on transport simulations for the JT-60SA divertor, the feasibility of the system is assessed. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ion cyclotron heating at high plasma density in Proto-MPEX

Author

Goulding, R. H., primary, Lau, C. H., additional, Piotrowicz, P. A., additional, Beers, C. J., additional, Biewer, T. M., additional, Caneses, J. F., additional, Caughman, J. B., additional, Kafle, N., additional, and Rapp, J., additional

Published

2023

4. Implementation of a portable diagnostic system for Thomson scattering measurements on an electrothermal arc source

Author

He, Z., primary, Kafle, N., additional, Gebhart, T. E., additional, Biewer, T. M., additional, and Zhang, Z., additional

Published

2022

5. Portable diagnostic package for Thomson scattering and optical emission spectroscopy on Princeton field-reversed configuration 2 (PFRC 2)

Author

Kafle, N., primary, Elliott, D., additional, Berlinger, B., additional, He, Z., additional, Cohen, S., additional, Zhang, Z., additional, and Biewer, T. M., additional

Published

2022

6. Final Design of the Material Plasma Exposure eXperiment

Author

Rapp, J., Lumsdaine, A., Aaron, A., Biewer, T. M., Bigelow, T. S., Boyd, T., Caughman, J. B. O., Curry, D., Duckworth, R. C., Goulding, R. H., Hussain, A., Kaufman, M., and Lau, C. H.

Abstract

AbstractThe Material Plasma Exposure eXperiment (MPEX) has completed its design phase. MPEX will be a unique facility to investigate plasma material interactions (PMIs) under fusion prototypic divertor conditions in steady state. This includes plasma exposure conditions expected in a fusion reactor divertor. Materials to be investigated will include solids, liquids, and neutron pre-irradiated materials. Electron and ion heating will allow for a large operational domain ranging from erosion-dominated PMI conditions to deposition-dominated PMI conditions. An overview of the final design for all MPEX systems is given. In particular, it is shown how mission-driven project requirements have led to detailed design choices with innovative solutions. Examples are the water-cooled helicon window, the electron cyclotron heating launcher, the target holder and manipulator, and the autonomous decouplers.

Published

2023

7. Power transport efficiency during O-X-B 2nd harmonic electron cyclotron heating in a helicon linear plasma device 1

Author

Marin, J F Caneses, primary, Lau, C L, additional, Goulding, R H, additional, Bigelow, T, additional, Biewer, T M, additional, Caughman, J B O, additional, and Rapp, J, additional

Published

2021

8. Reconfiguration of an Electrothermal-Arc Plasma Source for In Situ PMI Studies

Author

Lindquist, E. G., Gebhart, T. E., Elliott, D., Garren, E. W., He, Z., Kafle, N., Smith, C. D., Thomas, C. E., Zinkle, S. J., and Biewer, T. M.

Abstract

AbstractAn electrothermal-arc plasma source (ET-Arc) has been developed to produce transient plasma heat and particle fluxes similar to those produced by edge localized modes onto divertor plasma-facing components in tokamaks. The ET-Arc utilizes a capacitive discharge to send current through a 4-mm-diameter, 9-cm-long capillary source liner. The liner material is ablated to form a high-velocity plasma jet that impacts the target downstream. With the current discharge circuit configuration, pulse lengths are 1 to 2 ms in duration and deliver heat fluxes of 0.25 to 2.1 GW m−2. The plasma was previously characterized with optical emission spectroscopy (OES) on helium emission lines. The He I line ratios were interpreted with collisional radiative analysis to calculate neand Te. The electron temperature and electron density ranged from Te = 1 to 5 eV and ne = 1022to 1028 electrons/m3, respectively.Recently, the vacuum configuration and target of the ET-Arc device were modified to allow greater diagnostic access for plasma-material interaction (PMI) studies and diagnostic development. The diagnostic suite included two Tektronix high-voltage probes to measure the capacitor and discharge potentials, a discharge current monitor, Edgertronic SC1 high-speed cameras to image the discharge, and a FLIR SC4000 infrared camera to estimate heat flux on the target. The system used OES for plasma characterization, but a new Thomson scattering (TS) diagnostic has been implemented. This system is an Advanced Research Projects Agency - Energy (ARPA-E)-funded, portable diagnostic package for spectroscopic measurements of ne, Te, ni, Ti,, and vi, which includes both TS and OES. Additionally, a novel digital holography (DH) surface-imaging diagnostic was implemented to measure erosion rates in situ. Results from ex situ DH characterization of stainless steel targets exposed to the ET-Arc source indicated that surface erosion of ~150 nm per shot occurred and an in situ DH characterization of similar targets was planned. The arc-triggering system will be revised and optimized to better synchronize with the laser diagnostics. Details of the reconfigured ET-Arc source are reported here.

Published

2021

9. Conceptual design of a Doppler spectrometer for 102 m/s cross-field flows in tokamak divertors.

Author

Fujii K, Sano R, Nakano T, Ronchi G, Park JS, Lore JD, Shafer M, and Biewer TM

Abstract

The cross-field transport in the scrape-off-layers (SOLs) and divertors in tokamaks is of a similar size to the poloidal component of the parallel flow, thereby significantly impacting the plasma transport there. However, its direct observation has been challenging because the drift velocity (102-103 m/s) is significantly below the detection limit of conventional diagnostics. To realize cross-field ion flow measurement, a variety of systematic uncertainties in the system must be narrowed down. Here, we develop a conceptual design of the Doppler spectrometry that enables us to measure the impurity flows with 102-m/s accuracy based on an in situ wavelength-calibration technique developed in the astrophysics field, the iodine-cell method. We discuss its properties and applicability. In particular, the scaling relation between wavelength accuracy and various spectroscopic parameters is newly presented, which suggests the high importance of the wavelength resolution of the system. Based on transport simulations for the JT-60SA divertor, the feasibility of the system is assessed., (© 2024 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).)

Published

2024