Your search keyword '"Ostrowski, E. T."' showing total 7 results

1. Quantitative Measurement of Positive and Negative Ion Species Ejected from a Li–O–H Surface by Hydrogen and Noble Gas Ion Irradiation

Author

Abe, S., Ostrowski, E. T., Maan, A., Krstic, P., Majeski, R., and Koel, B. E.

Published

2023

2. Hydrogen irradiation-driven computational surface chemistry of lithium oxide and hydroxide.

Author

Krstic, P. S., Dwivedi, S., Ostrowski, E. T., Abe, S., Maan, A., van Duin, A. C. T., and Koel, B. E.

Subjects

COMPUTATIONAL chemistry, SURFACE chemistry, LITHIUM hydroxide, CHEMICAL reactions, CHEMICAL chains, COLLISION broadening

Abstract

We have investigated, using molecular dynamics, the surface chemistry of hydrogen incident on the amorphous and crystalline lithium oxide and lithium hydroxide surfaces upon being slowed down by a collision cascade and retained in the amorphous surface of either Li2O or LiOH. We looked for the bonding of H to the resident structures in the surface to understand a possible chain of chemical reactions that can lead to surface transformation upon H atom impact. Our findings, using Density-Functional Theory (DFT) trained ReaxFF force field/electronegativity equalization method potentials, stress the importance of inclusion of polarization in the dynamics of a Li–O–H system, which is also illustrated by DFT energy minimization and quantum–classical molecular dynamics using tight binding DFT. The resulting polar-covalent chemistry of the studied systems is complex and very sensitive to the instantaneous positions of all atoms as well as the ratio of concentrations of various resident atoms in the surface. [ABSTRACT FROM AUTHOR]

Published

2023

3. Detailed studies of the processes in low energy H irradiation of Li and Li-compound surfaces.

Author

Krstic, P. S., Ostrowski, E. T., Dwivedi, S., Abe, S., Maan, A., van Duin, A. C. T., and Koel, B. E.

Subjects

*COMPUTATIONAL physics, *HYDROGEN isotopes, *PLASMA confinement, *LITHIUM compounds, *HYDROGEN plasmas, *SURFACE chemistry, *IRRADIATION, *HYDROGEN as fuel

Abstract

We have used a combination of pico-to-nano temporal/spatial scale computational physics and chemistry modeling of plasma–material interfaces in the tokamak fusion plasma edges to unravel the evolving characteristics, not readily accessible by empirical means, of lithium-, oxygen-, and hydrogen-containing materials of plasma-facing components under irradiation by hydrogen and its isotopes. In the present calculation, amorphous lithium compound surfaces containing oxygen, Li2O, and LiOH were irradiated by 1–100 eV particles at incident angles on the surface ranging from perpendicular to almost grazing angles. Consequential surface processes, reflection, retention, and sputtering were studied at "the same footing" and compared to earlier results from amorphous Li and LiH surfaces. The critical role of charging dynamics of lithium, oxygen, and hydrogen atoms in the surface chemistry during hydrogen-fuel irradiation was found to drive the kinetics and dynamics of these surfaces in unexpected ways that ultimately could have profound effects on fusion plasma confinement behavior and surface erosion. [ABSTRACT FROM AUTHOR]

Published

2023

4. Energy, angle, and temperature dependencies of the sticking of D atoms on Li surfaces.

Author

Krstic, P. S., Abe, S., Schiltz-Rouse, E., Ostrowski, E. T., and Koel, B. E.

Subjects

DEUTERIUM, MOLECULAR dynamics, ATOMS

Abstract

Detailed experimental and computational information on the response of lithium surfaces to irradiation by slow hydrogenic particles (ions, atoms, molecules) is sparse and mainly speculative. In this work, we present a computational study of the reflection and retention of deuterium (D) atoms at crystalline and amorphous lithium surfaces at 300 and 500 K, where the D atoms have an impact energy in the range of 0.025–5 eV and incident angles of 0° (perpendicular incidence) or 85° (near-grazing incidence). Classical molecular dynamics simulations are performed with the reactive bond-order force field (ReaxFF) potentials. This study provides quantitative information on the deuterium sticking probability and recycling coefficient for lithium surfaces. Our results support the ongoing work at the Lithium Tokamak eXperiment-β fusion experiment as well as relevant experiments in the laboratory setting. [ABSTRACT FROM AUTHOR]

Published

2022

5. Estimates of global recycling coefficients for LTX-β discharges.

Author

Maan, A., Boyle, D. P., Majeski, R., Wilkie, G. J., Francisquez, M., Banerjee, S., Kaita, R., Maingi, R., LeBlanc, B. P., Abe, S., Jung, E., Perez, E., Capecchi, W., Ostrowski, E. T., Elliott, D. B., Hansen, C., Kubota, S., Soukhanovskii, V., and Zakharov, L.

Subjects

DISCHARGE coefficient, ELECTRON temperature, PLASMA temperature, LITHIUM, ION traps, FUSION reactor divertors

Abstract

We report the first observation of global recycling coefficient R near 0.5 in the Lithium Tokamak eXperiment-β (LTX-β), significantly below the minimum R previously reported in other devices. In a series of experiments with varied Li wall conditioning, estimates of the recycling coefficient have been made using a Lyman-α array and DEGAS2 modeling. A progressive reduction in Lyman-α emission with increased lithium and an increase in edge electron temperature are observed. It is also observed that with increasing Li coating thickness, the effective particle confinement time τ p * is reduced and approaches TRANSP calculated energy confinement time (τE), with τ p * near τ E , TRANSP for the lowest recycling coefficients. Edge temperatures approaching core plasma temperatures, first reported in LTX, can now be directly connected to estimates of the recycling coefficient and qualitatively agree with previous UEDGE simulations. The particle flux to the limiting surfaces appears to be significantly reduced in comparison with fluid scrape-off layer (SOL) models, indicating that a large fraction of the SOL ions are mirror trapped. SOL collisionality drops more than an order of magnitude below the banana regime boundary, indicating the importance of kinetic effects. Full-f 1x2v gyrokinetic simulations of SOL field lines with the GKEYLL code indicate that the fraction of ions trapped along field lines increases as collisionality drops, as a result of increased lithium evaporation. [ABSTRACT FROM AUTHOR]

Published

2024

6. Oxidation of lithium plasma facing components and its effect on plasma performance in the lithium tokamak experiment-β.

Author

Maan, A, Boyle, D P, Kaita, R, Ostrowski, E T, Donovan, D C, Majeski, R P, Koel, B E, Biewer, T M, Hughes, P E, Hansen, C, Kubota, S, and Soukhanovskii, V

Subjects

RARE earth oxides, X-ray photoelectron spectroscopy, LITHIUM compounds, ELECTRON temperature, SURFACE analysis

Abstract

The characteristics of lithium-coated plasma-facing components (PFCs) have been correlated with plasma performance on the lithium tokamak experiment-β (LTX-β). Previous experiments on LTX showed that the application of lithium to PFCs was needed to achieve higher performance discharges with flat electron temperature profiles and high edge temperatures. Samples that match the LTX-β PFCs were exposed to plasmas before and after PFCs were coated with lithium and transferred under vacuum to a surface analysis station. Measurements using x-ray photoelectron spectroscopy (XPS) revealed that the primary surface constituent was lithium oxide. Earlier XPS analysis of lithium-coated PFCs on LTX was only able to show the presence of surface oxygen. The new XPS data from LTX-β have sufficient resolution to clearly identify lithium compounds for the first time, and enable them to be correlated with how lithium-coated PFCs can reduce impurities and retain hydrogen to reduce recycling. [ABSTRACT FROM AUTHOR]

Published

2021

7. A simple vacuum suitcase for enabling plasma facing component characterization in fusion devices.

Author

Maan, A., Kaita, R., Ostrowski, E. T., Majeski, R., Boyle, D. P., Donovan, D. C., Ellis, R. A., Koel, B. E., and Biewer, T. M.

Subjects

SIGNAL-to-noise ratio, X-ray photoelectron spectroscopy, VACUUM, SUITCASES, SURFACE analysis

Abstract

We have demonstrated a vacuum suitcase to transport samples in vacuo to a surface analysis station for characterization of tokamak plasma facing components (PFCs). This technique enables surface analysis at powerful, dedicated stations that are not encumbered by design constraints imposed on them by a tokamak. The vacuum suitcase is an alternative solution to characterizing PFCs using diagnostics that are designed and built around a tokamak. The vacuum suitcase, called the Sample Exposure Probe (SEP), features mobile ultra-high vacuum pumping. Active pumping under high vacuum enables sample transfer between the Lithium Tokamak eXperiment-β (LTX-β) and a high resolution X-ray Photoelectron Spectroscopy (XPS) system that is situated close by. A thermocouple inserted in the back of the sample head measures heat flux from the plasma during exposure, and together with a button heater, allows the sample to match the LTX-β PFCs in high temperature operations. As vacuum conditions are better during transfer and analysis than in the tokamak, less contamination is introduced to the samples. XPS scans on a dedicated analysis station enable peak identification due to higher resolution and signal to noise ratio. A similar probe could be implemented for other fusion devices. The SEP is the first vacuum suitcase implementation for fusion applications that incorporates active pumping. [ABSTRACT FROM AUTHOR]

Published

2020