Publications
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CREEP RESISTANCE OF CMSX-3 NICKEL-BASE SUPERALLOY SINGLE-CRYSTALS (VOL 40, PG 1, 1992). ACTA METALLURGICA ET MATERIALIA. 41:2253–2253.
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1993. Creep resistance of nickel-base superalloy single crystals. Creep and fracture of engineering materials and structures. :287–301.
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1990. Creep-induced planar defects in L1 2-containing Co-and CoNi-base single-crystal superalloys. Acta Materialia. 82:530–539.
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2015. The Critical Role of Shock Melting in Ultrafast Laser Machining. Minerals, Metals and Materials Society/AIME, 420 Commonwealth Dr., P. O. Box 430 Warrendale PA 15086 United States.[np]. Feb.
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2011. Crystallographic fatigue crack initiation in nickel-based superalloy René 88DT at elevated temperature. Acta Materialia. 57:5964–5974.
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2009. Crystallography and elastic anisotropy in fatigue crack nucleation at nickel alloy twin boundaries. Journal of the Mechanics and Physics of Solids. 155:104538.
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2021. Cyclic oxidation of high temperature coatings on new $\gamma$′-strengthened cobalt-based alloys. Corrosion Science. 75:300–308.
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2013. Cyclic oxidation of Ru-containing single crystal superalloys at 1100 C. Materials Science and Engineering: A. 458:184–194.
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2007. Damage mechanism identification in composites via machine learning and acoustic emission. npj Computational Materials. 7:95.
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2021. Damage mechanism identification in composites via machine learning and acoustic emission. npj Computational Materials. 7:95.
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2021. Damage mechanisms during very high cycle fatigue of a coated and grit-blasted Ni-based single-crystal superalloy. International Journal of Fatigue. 142
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2021. Damage mechanisms during very high cycle fatigue of a coated and grit-blasted Ni-based single-crystal superalloy. International Journal of Fatigue. 142
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2021. Damage Nucleation During Transverse Creep of a Directionally Solidified Ni-based Superalloy. Materials Science and Engineering A. 858:144089.
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2022. Damage Nucleation During Transverse Creep of a Directionally Solidified Ni-based Superalloy. Materials Science and Engineering A. 858:144089.
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2022. A Data-Driven Bayesian Model for Predicting Fatigue Crack Nucleation in Polycrystalline Ni-Based Superalloys. SSRN Electronic Journal.
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2021. A Data-Driven Bayesian Model for Predicting Fatigue Crack Nucleation in Polycrystalline Ni-Based Superalloys. SSRN Electronic Journal.
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2021. Data-driven Bayesian model-based prediction of fatigue crack nucleation in Ni-based superalloys. npj Computational Materials. 8
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2022. Data-driven Bayesian model-based prediction of fatigue crack nucleation in Ni-based superalloys. npj Computational Materials. 8
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2022. Decoupling build orientation-induced geometric and texture effects on the mechanical response of additively manufactured IN625 thin-walled elements. Materials Science and Engineering: A. 870:144826.
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2023. Defect reduction in large superalloy castings by liquid-tin assisted solidification.. PARSONS 2003: Sixth International Charles Parsons Turbine Conference. :649–661.
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2003. Defects and 3D structural inhomogeneity in electron beam additively manufactured Inconel 718. Materials Characterization. 143:171–181.
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2018. Defects and 3D structural inhomogeneity in electron beam additively manufactured Inconel 718. Materials Characterization. 143:171–181.
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2018. Deformation and strain storage mechanisms during high-temperature compression of a powder metallurgy nickel-base superalloy. Metallurgical and Materials Transactions A. 41:2002–2009.
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2010. Deformation mechanisms in a Ru–Ni–Al ternary B2 intermetallic alloy. Acta materialia. 55:2715–2727.
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2007. Deformation of a platinum-containing RuAl intermetallic by< 111> dislocations. Scripta materialia. 48:1087–1092.
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2003.