| Year |
Citation |
Score |
| 2013 |
Hamilton B, Oppenheimer S, Dunand DC, Lewis D. Diffusion Bonding of Ti-6Al-4V Sheet with Ti-6Al-4V Foam for Biomedical Implant Applications Metallurgical and Materials Transactions B. 44: 1554-1559. DOI: 10.1007/S11663-013-9942-5 |
0.468 |
|
| 2012 |
Kearsey RM, Tsang J, Oppenheimer S, McDevitt E. Microstructural Effects on the Mechanical Properties of ATI 718Plus® Alloy Jom. 64: 241-251. DOI: 10.1007/S11837-012-0242-3 |
0.349 |
|
| 2012 |
Peterson B, Frias D, Brayshaw D, Helmink R, Oppenheimer S, Ott E, Benn R, Uchic M. On the development of cast ATI 718PLUS® alloy for structural gas turbine engine components Proceedings of the International Symposium On Superalloys. 787-794. DOI: 10.1002/9781118516430.Ch87 |
0.325 |
|
| 2011 |
Tsang J, Kearsey RM, Au P, Oppenheimer S, McDevitt E. Microstructural study of fatigue and dwell fatigue crack growth behaviour of ATI 718Plus alloy Canadian Metallurgical Quarterly. 50: 222-229. DOI: 10.1179/1879139511Y.0000000015 |
0.306 |
|
| 2010 |
Tsang J, Kearsey R, Au P, Seo D, Oppenheimer S, Cao W. Effect of composition and microstructure on the fatigue and creep-fatigue behaviour of Allvac 718Plus alloy Materials At High Temperatures. 27: 79-88. DOI: 10.3184/096034009X12604660943666 |
0.357 |
|
| 2010 |
Oppenheimer S, Dunand DC. Solid-state foaming of Ti-6A1-4V by creep or superplastic expansion of argon-filled pores Acta Materialia. 58: 4387-4397. DOI: 10.1016/J.Actamat.2010.04.034 |
0.517 |
|
| 2010 |
Kearsey RM, Tsang J, Au P, Oppenheimer S, McDevitt E. Systematic Evaluation of Microstructural Effects on the Mechanical Properties of ATI 718Plus(®) Alloy Superalloys. 780-797. DOI: 10.1002/9781118495223.Ch60 |
0.328 |
|
| 2010 |
Oppenheimer S, McDevitt E, Cao WD. Toughness as a function of thermo-mechanical processing and heat treatment in 718Plus® superalloy 7th International Symposium On Superalloy 718 and Derivatives 2010. 1: 321-330. DOI: 10.1002/9781118495223.Ch24 |
0.329 |
|
| 2009 |
Oppenheimer SM, Dunand DC. Porous NiTi by creep expansion of argon-filled pores Materials Science and Engineering A. 523: 70-76. DOI: 10.1016/J.Msea.2009.05.045 |
0.459 |
|
| 2008 |
Sargeant TD, Oppenheimer SM, Dunand DC, Stupp SI. Titanium foam-bioactive nanofiber hybrids for bone regeneration. Journal of Tissue Engineering and Regenerative Medicine. 2: 455-62. PMID 18850672 DOI: 10.1002/Term.117 |
0.412 |
|
| 2008 |
Sargeant TD, Guler MO, Oppenheimer SM, Mata A, Satcher RL, Dunand DC, Stupp SI. Hybrid bone implants: self-assembly of peptide amphiphile nanofibers within porous titanium. Biomaterials. 29: 161-71. PMID 17936353 DOI: 10.1016/J.Biomaterials.2007.09.012 |
0.429 |
|
| 2008 |
Kwok P, Oppenheimer S, Dunand D. Porous Titanium by Electro-chemical Dissolution of Steel Space-holders Advanced Engineering Materials. 10: 820-825. DOI: 10.1002/Adem.200800072 |
0.401 |
|
| 2007 |
OPPENHEIMER S, YUNG A, DUNAND D. Power-law creep in near-equiatomic nickel–titanium alloys Scripta Materialia. 57: 377-380. DOI: 10.1016/J.Scriptamat.2007.05.004 |
0.414 |
|
| 2007 |
Oppenheimer SM, Dunand DC. Finite element modeling of creep deformation in cellular metals Acta Materialia. 55: 3825-3834. DOI: 10.1016/J.Actamat.2007.02.033 |
0.405 |
|
| 2006 |
Shen H, Oppenheimer SM, Dunand DC, Brinson LC. Numerical modeling of pore size and distribution in foamed titanium Mechanics of Materials. 38: 933-944. DOI: 10.1016/J.Mechmat.2005.06.027 |
0.432 |
|
| 2005 |
Greiner C, Oppenheimer SM, Dunand DC. High strength, low stiffness, porous NiTi with superelastic properties. Acta Biomaterialia. 1: 705-16. PMID 16701851 DOI: 10.1016/J.Actbio.2005.07.005 |
0.464 |
|
| 2004 |
Li H, Oppenheimer SM, Stupp SI, Dunand DC, Brinson LC. Effects of pore morphology and bone ingrowth on mechanical properties of microporous titanium as an orthopaedic implant material Materials Transactions. 45: 1124-1131. DOI: 10.2320/Matertrans.45.1124 |
0.464 |
|
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