Publications

Wong, Chun-Shang W.; Kolasinski, Robert K.; Whaley, Josh A.

Abstract not provided.

Surface Science

Kolasinski, Robert K.; Whaley, Josh A.; Ward, Donald K.

This study examines channeling, multiple scattering, and neutralization/re-ionization of ions scattered along the stepped Al(332) plane. Our experimental approach involves probing the surface with 1–2 keV He+ and Ne+ beams, and then systematically mapping the scattered ion fluxes over a large solid angle. This provides comprehensive ion channeling information over all directions, rather than along a few low-index azimuths, as is common practice in ion scattering spectroscopy. We first probe the surface with 2 keV He+ at near-normal incidence, and then map the backscattered particle flux (both ions and neutrals) via time of flight (TOF) spectrometry. The features contained in these maps can be correlated with axial and inter-planar channeling effects, and are reproduced well via binary collision simulations. Sensitivity to the stepped surface topography is heightened considerably for oblique ion incidence in the forward-scattering direction. In this geometry, we used 2 keV Ne+ to probe the surface and mapped the corresponding scattered fluxes of both single and multiply-charged ions. In both cases, the scattering intensity depends strongly on the precise trajectory taken along the surface, and is particularly sensitive to how extensively the incident ions interact with the step edges. We interpret the information contained in these maps by considering several mechanisms for charge transfer and double ion production. The formation of Ne++ appears to be correlated with a previously observed inelastic mechanism that occurs when the collision apsis, Rmin, is less than 0.65 Å. This contributes to an energy loss of 48 ± 8 eV for Ne+ undergoing single scattering; the Rmin threshold for this inelastic step coincides with the emergence of a distinct Ne++ peak. Using the information gained from the maps, we propose methods for extending this approach to chemisorbed layers.

Kolasinski, Robert K.; Dasgupta, Dwaipayan D.; Whaley, Josh A.; Engel, Aaron E.; Allen, Frances A.; Buchenauer, D.A.; Maroudas, Dimitrios M.; Wirth, Brian W.

Abstract not provided.

White, James L.; Rowberg, Andrew J.; Wan, Liwen F.; Kang, ShinYoung K.; Ogitsu, Tadashi O.; Kolasinski, Robert K.; Whaley, Josh A.; Wang, Timothy C.; Baker, Alexander A.; Lee, Jonathan R.; Liu, Yi-Sheng L.; Guo, Jinghua G.; Stavila, Vitalie S.; Prendergast, David P.; Bluhm, Hendrik B.; Allendorf, Mark D.; Wood, Brandon C.; El Gabaly Marquez, Farid E.

Abstract not provided.

Kolasinski, Robert K.; Buchenauer, D.A.; Kobayashi, Makoto K.; Whaley, Josh A.; Oya, Yasuhisa O.

Abstract not provided.

Kolasinski, Robert K.; Whaley, Josh A.; Engel, Aaron E.; Shone, Andrew S.; Buchenauer, D.A.; Allen, Frances A.

Abstract not provided.

Proposed for publication

White, James L.; Rowberg, Andrew J.; Wan, Liwen F.; Kang, ShinYoung K.; Ogitsu, Tadashi O.; Kolasinski, Robert K.; Whaley, Josh A.; Baker, Alexander A.; Lee, Jonathan R.; Liu, Yi-Sheng L.; Trotochaud, Lena T.; Guo, Jinghua G.; Stavila, Vitalie S.; Prendergast, David P.; Bluhm, Hendrik B.; Allendorf, Mark D.; Wood, Brandon C.; El Gabaly Marquez, Farid E.

Abstract not provided.

Kolasinski, Robert K.; Whaley, Josh A.; Friddle, Raymond W.; Buchenauer, D.A.; Allen, Frances A.; Ferro, Yves F.; Piazza, Zachary P.; Ajmalghan, Muthali A.; Dasgupta, Dwaipayan D.; Maroudas, Dimitrios M.; Wirth, Brian W.

Abstract not provided.

Kolasinski, Robert K.; Whaley, Josh A.; El Gabaly Marquez, Farid E.; Klebanoff, Leonard E.; Stavila, Vitalie S.; White, James L.; Allendorf, Mark D.

Abstract not provided.

Reyes, Karla R.; Withey, Elizabeth A.; Whaley, Josh A.; Chames, Jeffery M.; Sugar, Joshua D.; Bartelt, Norman C.

Abstract not provided.

Kolasinski, Robert K.; Buchenauer, D.A.; Whaley, Josh A.; Allen, Frances A.

Abstract not provided.

Kolasinski, Robert K.; Whaley, Josh A.; Stavila, Vitalie S.; White, James L.; El Gabaly Marquez, Farid E.; Allendorf, Mark D.

Abstract not provided.

Fusion Engineering and Design

Buchenauer, D.A.; Karnesky, Richard A.; Fang, Zhigang Z.; Ren, Chai; Oya, Yasuhisa; Otsuka, Teppei; Yamauchi, Yuji; Whaley, Josh A.

To address the transport and trapping of hydrogen isotopes, several permeation experiments are being pursued at both Sandia National Laboratories (deuterium gas-driven permeation) and Idaho National Laboratories (tritium gas- and plasma-driven tritium permeation). These experiments are in part a collaboration between the US and Japan to study the performance of tungsten at divertor relevant temperatures (PHENIX). Here we report on the development of a high temperature (≤1150 °C) gas-driven permeation cell and initial measurements of deuterium permeation in several types of tungsten: high purity tungsten foil, ITER-grade tungsten (grains oriented through the membrane), and dispersoid-strengthened ultra-fine grain (UFG) tungsten being developed in the US. Experiments were performed at 500–1000 °C and 0.1–1.0 atm D2 pressure. Permeation through ITER-grade tungsten was similar to earlier W experiments by Frauenfelder (1968–69) and Zaharakov (1973). Data from the UFG alloy indicates marginally higher permeability (< 10×) at lower temperatures, but the permeability converges to that of the ITER tungsten at 1000 °C. The permeation cell uses only ceramic and graphite materials in the hot zone to reduce the possibility for oxidation of the sample membrane. Sealing pressure is applied externally, thereby allowing for elevation of the temperature for brittle membranes above the ductile-to-brittle transition temperature.

AIP Conference Proceedings

Ermanoski, Ivan E.; Grobbel, Johannes G.; Singh, Abhishek S.; Lapp, Justin L.; Brendelberger, Stefan B.; Sattler, Christian S.; Whaley, Josh A.; McDaniel, Anthony H.; Siegel, Nathan S.

Recent work regarding the efficiency maximization for solar thermochemical fuel production in two step cycles has led to the design of a new type of reactor—the cascading pressure reactor—in which the thermal reduction step of the cycle is completed in multiple stages, at successively lower pressures. This approach enables lower thermal reduction pressures than in single-staged reactors, and decreases required pump work, leading to increased solar to fuel efficiencies. In this work we report on the design and construction of a prototype cascading pressure reactor and testing of some of the key components. We specifically focus on the technical challenges particular to the design, and their solutions.

AIP Conference Proceedings

Ermanoski, Ivan E.; Grobbel, Johannes; Singh, Abhishek; Lapp, Justin; Brendelberger, Stefan; Roeb, Martin; Sattler, Christian; Whaley, Josh A.; McDaniel, Anthony H.; Siegel, Nathan P.

Recent work regarding the efficiency maximization for solar thermochemical fuel production in two step cycles has led to the design of a new type of reactor - the cascading pressure reactor - in which the thermal reduction step of the cycle is completed in multiple stages, at successively lower pressures. This approach enables lower thermal reduction pressures than in single-staged reactors, and decreases required pump work, leading to increased solar to fuel efficiencies. Here we report on the design and construction of a prototype cascading pressure reactor and testing of some of the key components. We especially focus on the technical challenges particular to the design, and their solutions.

Kolasinski, Robert K.; Whaley, Josh A.; Buchenauer, D.A.

Abstract not provided.

Buchenauer, D.A.; Karnesky, Richard A.; Kolasinski, Robert K.; Whaley, Josh A.; Donovan, David D.; Fang, Zhigang Z.; Ren, Chai R.

Abstract not provided.

Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

Antolak, Arlyn J.; Leung, K.N.; Morse, D.H.; Donovan, D.C.; Chames, J.M.; Whaley, Josh A.; Buchenauer, D.A.; Chen, A.X.; Hausladen, P.A.; Liang, F.

An associated particle neutron generator is described that employs a negative ion source to produce high neutron flux from a small source size. Negative ions produced in an rf-driven plasma source are extracted through a small aperture to form a beam which bombards a positively biased, high voltage target electrode. Electrons co-extracted with the negative ions are removed by a permanent magnet electron filter. The use of negative ions enables high neutron output (100% atomic ion beam), high quality imaging (small neutron source size), and reliable operation (no high voltage breakdowns). The neutron generator can operate in either pulsed or continuous-wave (cw) mode and has been demonstrated to produce 106 D-D n/s (equivalent to ~108 D-T n/s) from a 1 mm-diameter neutron source size to facilitate high fidelity associated particle imaging.

Karnesky, Richard A.; Friddle, Raymond W.; Whaley, Josh A.; Smith, Geoffrey S.

This report analyzes the permeation resistance of a novel and proprietary polymer coating for hydrogen isotope resistance that was developed by New Mexico State University. Thermal gravimetric analysis and thermal desoprtion spectroscopy show the polymer is stable thermally to approximately 250 deg C. Deuterium gas-driven permeation experiments were conducted at Sandia to explore early evidence (obtained using Brunauer - Emmett - Teller) of the polymer's strong resistance to hydrogen. With a relatively small amount of the polymer in solution (0.15%), a decrease in diffusion by a factor of 2 is observed at 100 and 150 deg C. While there was very little reduction in permeability, the preliminary findings reported here are meant to demonstrate the sensitivity of Sandia's permeation measurements and are intended to motivate the future exploration of thicker barriers with greater polymer coverage.

Buchenauer, D.A.; Karnesky, Richard A.; Kolasinski, Robert K.; Whaley, Josh A.; Donovan, David D.; Fang, Zhigang Z.; Ren, Chai R.; Oya, Yasuhisa O.; Chikada, Takumi C.; Michibayashi, Katsuyoshi M.; Otsuka, Teppei O.; Yamauchi, Yuji Y.

Abstract not provided.

Buchenauer, D.A.; Karnesky, Richard A.; Fang, Zhingang Z.; Ren, Chai R.; Oya, Yasuhisa O.; Otsuka, Teppei O.; Yamauchi, Yuji Y.; Whaley, Josh A.

Abstract not provided.

Buchenauer, D.A.; Karnesky, Richard A.; Fang, Zhingang Z.; Ren, Chai R.; Oya, Yasuhisa O.; Otsuka, Teppei O.; Yamauchi, Yuji Y.; Whaley, Josh A.

Abstract not provided.

Journal of Nuclear Materials

Kolasinski, Robert K.; Hammond, K.D.; Whaley, Josh A.; Buchenauer, D.A.; Wirth, B.D.

Abstract In this work, we apply low energy ion beam analysis to examine directly how the adsorbed hydrogen concentration and binding configuration on W(1 0 0) depend on temperature. We exposed the tungsten surface to fluxes of both atomic and molecular H and D. We then probed the H isotopes adsorbed along different crystal directions using 1-2 keV Ne⁺ ions. At saturation coverage, H occupies two-fold bridge sites on W(1 0 0) at 25°C. The H coverage dramatically changes the behavior of channeled ions, as does reconstruction of the surface W atoms. For the exposure conditions examined here, we find that surface sites remain populated with H until the surface temperature reaches 200°C. After this point, we observe H rapidly desorbing until only a residual concentration remains at 450°C. Development of an efficient atomistic model that accurately reproduces the experimental ion energy spectra and azimuthal variation of recoiled H is underway.

Reyes, Karla R.; Whaley, Josh A.; Nishimoto, Ryan K.; Yang, Nancy Y.

Abstract not provided.

Reyes, Karla R.; Whaley, Josh A.; Nishimoto, Ryan K.; Yang, Nancy Y.

Abstract not provided.