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Nanoscale structural heterogeneity in Ni-rich half-Heusler TiNiSn. Journal of Applied Physics. 116:163514.. 2014.
Three-dimensional multimodal imaging and analysis of biphasic microstructure in a Ti–Ni–Sn thermoelectric material. APL Materials. 3:096107.. 2015.
Magnetic hardening and antiferromagnetic/ferromagnetic phase coexistence in Mn 1- x Fe x Ru 2 Sn Heusler solid solutions. Physical Review B. 94:094412.. 2016.
Enhanced thermoelectric properties of bulk TiNiSn via formation of a TiNi2Sn second phase. Applied Physics Letters. 101:183902.. 2012.
Phase stability and property evolution of biphasic Ti–Ni–Sn alloys for use in thermoelectric applications. Journal of Applied Physics. 115:043720.. 2014.
Formation of secondary reaction zone in ruthenium bearing nickel based single crystal superalloys with diffusion aluminide coatings. Materials Science and Technology. 25:300–308.. 2009.
Depth-profiling study of a thermal barrier coated superalloy using femtosecond laser-induced breakdown spectroscopy. Spectrochimica Acta Part B: Atomic Spectroscopy. 63:27–36.. 2008.
Detection of a marker layer in a 7YSZ thermal barrier coating by femtosecond laser-induced breakdown spectroscopy. Surface and Coatings Technology. 202:3940–3946.. 2008.
Femtosecond laser machining of cooling holes in thermal barrier coated CMSX4 superalloy. Journal of Materials Processing Technology. 209:5661–5668.. 2009.
Femtosecond pulsed laser damage characteristics of 7% Y2O3-ZrO2 thermal barrier coating. Applied Physics A. 91:421–428.. 2008.
Qualitative Characterization of a Thermal Barrier Coating System Using Femtosecond Laser-Induced Breakdown Spectroscopy. MATERIALS SCIENCE AND TECHNOLOGY-ASSOCIATION FOR IRON AND STEEL TECHNOLOGY-. 5:621.. 2006.
Formation of secondary reaction zones in diffusion aluminide-coated Ni-base single-crystal superalloys containing ruthenium. Metallurgical and Materials Transactions A. 39:1647–1657.. 2008.
Effects of high temperature air and vacuum exposures on the room temperature tensile behavior of the (O+ B2) titanium aluminide Ti-22Al-23Nb. Materials Science and Engineering: A. 208:188–202.. 1996.
Effects of environment on the tensile and creep behavior of a low-oxygen orthorhombic-based titanium aluminide, Ti-22 Al-23 Nb. Titanium'95- Science and technology. :396–403.. 1996.