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374 results on '"Smith, Timothy M."'

1. Dissolution zone model of the oxide structure in additively manufactured dispersion-strengthened alloys

Author

Hou, Wenyuan, Stubbs, Timothy, DeBeer-Schmitt, Lisa, Chang, Yen-Ting, Charpagne, Marie-Agathe, Smith, Timothy M., Huang, Aijun, and Cordero, Zachary C.

Subjects
Condensed Matter - Materials Science
Abstract

The structural evolution of oxides in dispersion-strengthened superalloys during laser-powder bed fusion is considered in detail. Alloy chemistry and process parameter effects on oxide structure are assessed through a parameter study on the model alloy Ni-20Cr, doped with varying concentrations of Y2O3 and Al. A scaling analysis of mass and momentum transport within the melt pool, presented here, establishes that diffusional structural evolution mechanisms dominate for nanoscale dispersoids, while fluid forces and advection become significant for larger micron-scale slag inclusions. These findings are developed into a theory of dispersoid structural evolution, integrating quantitative models of diffusional processes -- dispersoid dissolution, nucleation, growth, coarsening -- with a reduced order model of time-temperature trajectories of fluid parcels within the melt pool. Calculations of the dispersoid size in single-pass melting reveal a zone in the center of the melt track in which the oxide feedstock fully dissolves. Within this zone the final Y2O3 size is independent of feedstock size and determined by nucleation and growth kinetics. If the dissolution zones of adjacent melt tracks overlap sufficiently with each other to dissolve large oxides, formed during printing or present in the powder feedstock, then the dispersoid structure throughout the build volume is homogeneous and matches that from a single pass within the dissolution zone. Gaps between adjacent dissolution zones result in oxide accumulation into larger slag inclusions. Predictions of final dispersoid size and slag formation using this dissolution zone model match the present experimental data and explain process-structure linkages speculated in the open literature.

Published
2024

2. Harnessing metastability for grain size control in multiprincipal element alloys during additive manufacturing

Author

Wakai, Akane, Bustillos, Jenniffer, Sargent, Noah, Stokes, Jamesa, Xiong, Wei, Smith, Timothy M., and Moridi, Atieh

Subjects
Condensed Matter - Materials Science
Abstract

Controlling microstructure in fusion-based metal additive manufacturing (AM) remains a challenge due to numerous parameters directly impacting solidification conditions. Multiprincipal element alloys (MPEAs) offer a vast compositional design space for microstructural engineering due to their chemical complexity and exceptional properties. Here, we establish a novel alloy design paradigm in MPEAs for AM using the FeMnCoCr system. By exploiting the decreasing phase stability with increasing Mn content, we achieve notable grain refinement and breakdown of columnar grain growth. We combine thermodynamic modeling, operando synchrotron X-ray diffraction, multiscale microstructural characterization, and mechanical testing to gain insight into the solidification physics and its ramifications on the resulting microstructure. This work paves way for tailoring grain sizes through targeted manipulation of phase stability, thereby advancing microstructure control in AM.

Published
2024

3. Limits of dispersoid size and number density in oxide dispersion strengthened alloys fabricated with powder bed fusion-laser beam

Author

Wassermann, Nathan A., Li, Yongchang, Myers, Alexander J., Kantzos, Christopher A., Smith, Timothy M., Beuth, Jack L., Malen, Jonathan A., Shao, Lin, McGaughey, Alan J. H., and Narra, Sneha P.

Subjects
Condensed Matter - Materials Science
Abstract

Previous work on additively-manufactured oxide dispersion strengthened alloys focused on experimental approaches, resulting in larger dispersoid sizes and lower number densities than can be achieved with conventional powder metallurgy. To improve the as-fabricated microstructure, this work integrates experiments with a thermodynamic and kinetic modeling framework to probe the limits of the dispersoid sizes and number densities that can be achieved with powder bed fusion-laser beam. Bulk samples of a Ni-20Cr $+$ 1 wt.% Y$_2$O$_3$ alloy are fabricated using a range of laser power and scanning velocity combinations. Scanning transmission electron microscopy characterization is performed to quantify the dispersoid size distributions across the processing space. The smallest mean dispersoid diameter (29 nm) is observed at 300 W and 1200 mm/s, with a number density of 1.0$\times$10$^{20}$ m$^{-3}$. The largest mean diameter (72 nm) is observed at 200 W and 200 mm/s, with a number density of 1.5$\times$10$^{19}$ m$^{-3}$. Scanning electron microscopy suggests that a considerable fraction of the oxide added to the feedstock is lost during processing, due to oxide agglomeration and the ejection of oxide-rich spatter from the melt pool. After accounting for these losses, the model predictions for the dispersoid diameter and number density align with the experimental trends. The results suggest that the mechanism that limits the final number density is collision coarsening of dispersoids in the melt pool. The modeling framework is leveraged to propose processing strategies to limit dispersoid size and increase number density., Comment: Main text: 37 pages, 20 figures

Published
2023
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4. The influence of processing methods on creep of wrought and additively manufactured CrCoNi multi-principal element alloys

Author

Sahragard-Monfared, Gianmarco, Zhang, Mingwei, Smith, Timothy M, Minor, Andrew M, George, Easo P, and Gibeling, Jeffery C

Subjects
Engineering, Materials Engineering, CrCoNi, Creep, Multi-principal element alloys, Oxides, Grain boundaries, Condensed Matter Physics, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics
Abstract

The influence of vacuum arc melting and mechanical processing (wrought) versus additive manufacturing (AM) on the creep behavior of multi-principal element alloys (MPEA) is investigated in this study. Annealed wrought and hot isostatically pressed (HIP) AM CrCoNi were creep tested under constant tensile stress of 40 to 200 MPa at temperatures of 1023 to 1173 K. Stress exponents of 4.5 ± 0.2 and 5.9 ± 0.1 and activation energies ranging from 240 to 259 and 320 to 331 kJ/mol were found for wrought and AM CrCoNi, respectively. The results indicate that the AM material exhibits superior creep resistance and inferior creep ductility compared to the wrought alloy. This difference is attributed to the AM material having a higher percentage of Cr-rich oxides, a smaller total low angle grain boundary (LAGB) length on a percentage basis, and a greater total twin boundary (TB) length on a percentage basis. The AM and wrought materials have similar grain sizes; however, the smaller LAGB length and greater TB length in the AM material reduce slip transmission on the other side of the boundaries and contribute to strength. The dislocation structures of the AM and wrought materials consist of individual curved dislocations with dislocation multijunctions and jogs, which is similar to the arrangements previously observed in CrMnFeCoNi.

Published
2023

5. Energy-composition relations in Ni$_3$(Al$_{1-x}$X$_x$) phases

Author

Zarkevich, Nikolai A., Smith, Timothy M., and Lawson, John W.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter, Physics - Applied Physics, Physics - Chemical Physics, Physics - Computational Physics
Abstract

The secondary phase, such as Ni$_3$Al-based $L1_2$ $\gamma^\prime$, is crucially important for precipitation strengthening of superalloys. Composition-structure-property relations provide useful insights for guided alloy design. Here we use density functional theory combined with the multiple scattering theory to compute dependencies of the structural energies and equilibrium volumes versus composition for ternary Ni$_3$(Al$_{1-x}$X$_x$) alloys with X=(Ti, Zr, Hf; V, Nb, Ta; Cr, Mo, W) in $L1_2$, $D0_{24}$, and $D0_{19}$ phases with a homogeneous chemical disorder on the (Al$_{1-x}$X$_x$) sublattice. Our results provide a better understanding of the physics in Ni$_3$Al-based precipitates and facilitate design of next-generation nickel superalloys with precipitation strengthening., Comment: 12 pages, 5 figures

Published
2023
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6. Energy landscape in NiCoCr-based middle-entropy alloys

Author

Zarkevich, Nikolai A., Smith, Timothy M., and Lawson, John W.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter, Physics - Chemical Physics, Physics - Computational Physics
Abstract

NiCoCr middle-entropy alloy is known for its exceptional strength at both low and elevated operating temperatures. Mechanical properties of NiCoCr-based alloys are affected by certain features of the energy landscape, such as the energy difference between the hcp and fcc phases (which is known to correlate with the stacking fault energy in the fcc phase) and curvature of the energy surface. We compute formation energies in the Ni-Co-Cr ternary and related quaternary systems and investigate dependences of the relative energies on composition. Such computed composition-structure-property relations can be useful for tuning composition and designing next-generation alloys with improved strength., Comment: 13 pages, 9 figures

Published
2023

7. Superior tensile creep behavior of a novel oxide dispersion strengthened CrCoNi multi-principal element alloy

Author

Sahragard-Monfared, Gianmarco, Zhang, Mingwei, Smith, Timothy M, Minor, Andrew M, and Gibeling, Jeffery C

Subjects
Engineering, Materials Engineering, CrCoNi, Creep, Multi -principal element alloys, Oxide dispersion strengthening, Additive manufacturing, Condensed Matter Physics, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics
Abstract

The creep behavior of an additively manufactured (AM) yttrium oxide dispersion strengthened (ODS) CrCoNi multi-principal element alloy (MPEA) is investigated in this study. Tests were conducted over a constant tensile stress range of 40–200 MPa and a temperature range of 973–1173 K. A stress exponent of 6.5 ± 0.1 and activation energies in the range of 335–367 kJ/mol were measured. Compared to its non-ODS counterpart and its parent alloy (CrMnFeCoNi), AM ODS CrCoNi has superior creep resistance at all tested stresses and temperatures. The mechanism contributing to the excellent creep resistance of AM ODS CrCoNi is attributed to the interaction of mixed character dislocations with oxide particles. The creep ductility of AM ODS CrCoNi is higher than its non-ODS counterpart due to a large percentage of low angle grain boundaries associated with its columnar grain structure. It was also found that creep ductility is significantly greater at the highest applied stress of 200 MPa compared to lower stresses. The steady state dislocation structure of AM ODS CrCoNi consists of long arrays of dislocations, which is different from that observed in non-ODS CrCoNi which consists of individual curved dislocations.

Published
2023

8. Effects of Alloying Elements on Twinning in Ni-Based Superalloys

Author

Borovikov, Valery V., Mendelev, Mikhail I., Smith, Timothy M., Lawson, John W., Cormier, Jonathan, editor, Edmonds, Ian, editor, Forsik, Stephane, editor, Kontis, Paraskevas, editor, O’Connell, Corey, editor, Smith, Timothy, editor, Suzuki, Akane, editor, Tin, Sammy, editor, and Zhang, Jian, editor

Published
2024
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18. Emerging Additive Manufacturing Technology for Propulsion

Author

Mireles, Omar R., primary, Lanigan, Erin, additional, Gradl, Paul R., additional, Wheeler, Kevin, additional, Smith, Timothy M., additional, Scannapieco, David, additional, Iten, Jeremy, additional, Roehling, John D., additional, Smith, William L., additional, Matthews, Manyalibo J., additional, and Plessis, Anton Du, additional

Published
2022
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20. Variability Reduction in NIRS Measurements for Reliable TBI Patient Monitoring

Author

Izzetoglu, Meltem, Ben-Dor, Baruch, Black, Jonathan, Ayaz, Hasan, Liptrap, Elizabeth, Stephens, Shannon W., Smith, Timothy M., Reynolds, Lindy, Richman, Joshua, Valadka, Alex, Holcomb, John Bradley, and Jansen, Jan O.

Abstract

Traumatic brain injury (TBI) is a leading cause of mortality and morbidity, commonly causing intracranial hematomas as a serious complication. While computerized tomography (CT) scans are the standard diagnostic tool for hematoma detection, their use for continuous monitoring is limited due to radiation risks and logistical difficulties. Near-infrared spectroscopy (NIRS) offers a noninvasive, portable, and cost-effective alternative, as evidenced by the Infrascanner—the first handheld device proven in clinical studies for hematoma detection. Despite its success in hematoma detection, the Infrascanner’s efficacy in tracking hematoma expansion remains unexplored. Our recent pilot studies with repeated recordings conducted to investigate Infrascanner’s potential as a monitoring device showed large signal variability (SD) even under unchanging or healthy conditions when its original protocols developed for hematoma detection are used. In this work, our primary goal was to develop novel data processing algorithms with a modified data collection regime and evaluate their performance in reducing SD in comparison to each other and the original algorithms. Our results suggested that among the proposed algorithms, the most promising was based on eliminating maximal values from hemispheric measurement pairs, resulting in significantly improved signal stability and overall device performance. Our key contributions in this study involve the development and evaluation of novel data collection and processing methods for the Infrascanner to reduce its SD and false alarm rate (FAR) while improving its sensitivity and correlation with hematoma size, which can further strengthen the potential utility of the Infrascanner in monitoring TBI patients for hematoma expansion.

Published
2024
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23. Environmental drivers of flowering in the genus Zostera and spatio‐temporal variability of Zostera muelleri flowering in Australasia

Author

Lekammudiyanse, Manuja U., primary, Saunders, Megan I., additional, Flint, Nicole, additional, Irving, Andrew, additional, Aiken, Christopher, additional, Clark, Dana E., additional, Berthelsen, Anna, additional, Hindmarsh, Breanna, additional, Hooks, Rachel, additional, Connolly, Rod M., additional, Sievers, Michael, additional, Rasheed, Michael A., additional, Smith, Timothy M., additional, Glasby, Tim M., additional, Sherman, Craig D. H., additional, and Jackson, Emma L., additional

Published
2024
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26. Impact of Powder Variability on the Microstructure and Mechanical Behavior of Selective Laser Melted Alloy 718

Author

Sudbrack, Chantal K., Lerch, Bradley A., Smith, Timothy M., Locci, Ivan E., Ellis, David L., Thompson, Aaron C., Richards, Benjamin, Ott, Eric, editor, Liu, Xingbo, editor, Andersson, Joel, editor, Bi, Zhongnan, editor, Bockenstedt, Kevin, editor, Dempster, Ian, editor, Groh, Jon, editor, Heck, Karl, editor, Jablonski, Paul, editor, Kaplan, Max, editor, Nagahama, Daisuke, editor, and Sudbrack, Chantal, editor

Published
2018
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36. Producing Next Generation Superalloys Through Advanced Characterization and Manufacturing Techniques

Author

Smith, Timothy M

Subjects
Metals And Metallic Materials
Abstract

NASA is currently working towards developing the next generation high temperature alloys for various aerospace and energy applications. Through advanced microscopy and computational insights, a novel atomic scale strengthening mechanism was discovered in Ni-base superalloys. This new local phase transformation strengthening technique has been successfully implemented resulting in new disk alloys with substantial improvements in creep strength over current state-of-the-art. Furthermore, additive manufacturing has been leveraged to produce dispersion strengthened (DS), multi-principal element alloys (MPEA) without the use of traditional mechanical alloying or chemical reactions. This new processing technique has successfully resulted in 99.9% dense oxide dispersion strengthened NiCoCr alloy parts. High temperature mechanical testing of the DS alloys showed significant improvements in strength and ductility over the baseline NiCoCr. As a result, this recently discovered processing route opens a new alloy design and production path that is synergistic between additive manufacturing and dispersion strengthening, possibly enabling a new generation of high-performance alloys.

Published
2020

37. Investigation of Stacking Fault and Antiphase Boundary Segregation in Ni-Based Superalloys Using Density Functional Theory

Author

Good, Brian S and Smith, Timothy M

Subjects
Metals And Metallic Materials
Abstract

Ni-base superalloys have a long history of use in jet turbine engines, and efforts to improve their performance in that application are ongoing. It is known that the precipitation of the Ni3Al γ' phase within the disordered FCCγ phase strengthens the overall material. However, in the high-temperature environment found inside a turbine engine during operation, creep can cause the γ' phase to transform to different, weaker phases along stacking faults, leading to a deterioration of performance. In the γ' phase one mode of creep deformation is the formation of stacking fault ribbons, which consist of intrinsic stacking faults further shearing into antiphase boundaries (APBs). It is also known that certain alloying additions exhibit segregation to stacking faults. If segregating elements could be identified which segregate to the intrinsic stacking fault, but not to the APB, the inclusion of such elements could lead to improved creep strength in these alloys. To investigate this possibility, a density functional investigation of the segregation of W, Mo and Cr to both a superlattice intrinsic stacking fault (SISF) and an APB was performed. It was found that W, Mo and Cr all exhibit segregation to the SISF. In contrast, for the APB, Cr was either energy-neutral, or segregates, depending on the presence of additional nearby Cr, or on the specific lattice site upon which it was placed, while Mo and W did not segregate. Because W and Mo segregate to the SISF but not to the APB, the inclusion of these elements could provide a degree of protection against creep-related deterioration.

Published
2019

42. Indirect grazing‐induced mechanisms contribute to the resilience of Mediterranean seagrass meadows to sea urchin herbivory

Author

Buñuel, Xavier, primary, Alcoverro, Teresa, additional, Boada, Jordi, additional, Zinkunegi, Leire, additional, Smith, Timothy M., additional, Barrera, Anaïs, additional, Casas, Marc, additional, Farina, Simone, additional, Pérez, Marta, additional, Romero, Javier, additional, Arthur, Rohan, additional, and Pagès, Jordi F., additional

Published
2023
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50. Transcriptomic changes underlying EGFR inhibitor resistance in human and mouse models of basal-like breast cancer

Author

Rashid, Narmeen S., primary, Boyd, David C., additional, Olex, Amy L., additional, Grible, Jacqueline M., additional, Duong, Alex K., additional, Alzubi, Mohammad A., additional, Altman, Julia E., additional, Leftwich, Tess J., additional, Valentine, Aaron D., additional, Hairr, Nicole S., additional, Zboril, Emily K., additional, Smith, Timothy M., additional, Pfefferle, Adam D., additional, Dozmorov, Mikhail G., additional, and Harrell, J. Chuck, additional

Published
2022
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