Parties d'ouvrages collectifs (1)
  1. 1. Pirgazi, H., Petrov, R. R., Malet, L., Godet, S., & Kestens, L. (2021). Recent Developments in Orientation Contrast Microscopy. In Encyclopedia of Materials: Metals and Alloys (pp. 662-681). Elsevier. doi:10.1016/B978-0-12-819726-4.00135-6
    2.   Articles dans des revues avec comité de lecture (41)
  2. 1. Nunes, A. R. V., Gabriel, S. S., Caio, C. M., Sales Araújo, L., Dille, J., Malet, L., Kaufman, M. J., & de Almeida, L. H. (2024). Effects of aging on the microstructure and mechanical properties of metastable β-type Ti-23.6Nb-5.1Mo-6.7Zr alloy with low elastic modulus. Journal of International Research Publications: Materials, Methods & Technologies, 31, 4104-4112. doi:10.1016/j.jmrt.2024.07.127
  3. 2. Kwaśniak, P., Dumas, O., Malet, L., Muzyk, M., Zemła, M. R., Godet, S., & Prima, F. (2024). Atomic scale mechanism of reorientation induced plasticity in titanium alloys - experimental and first principles investigation of the mobile {134‾1} interfaces. Materials & design, 242, 112947. doi:10.1016/j.matdes.2024.112947
  4. 3. Malet, L., & Godet, S. (2024). Influence of Austenite Grain Size on the Variant Configurations of Martensite in a Fe-30.5Ni-0.155C Alloy. Crystals, 14(5), 461. doi:10.3390/cryst14050461
  5. 4. Malet, L., & Godet, S. (2024). Revisiting the Crystallography of {225}γ Martensite: How EBSD Can Help to Solve Long-Standing Controversy. Crystals, 14(3), 287. doi:10.3390/cryst14030287
  6. 5. Dumas, O., Malet, L., Kwaśniak, P., Prima, F., & Godet, S. (2024). Design rules to develop solute lean α+β titanium alloys exhibiting high work-hardening by reorientation induced plasticity. Materials science & engineering. A, Structural materials: properties, microstructure and processing, 890, 145935. doi:10.1016/j.msea.2023.145935
  7. 6. Nunes, A. R. V., Gabriel, S. S., Araújo, L. L., Rodrigues, T. Z. L., Malet, L., Dille, J., & de Almeida, L. H. (2023). Influence of the Chemical Composition on the Phase Stability and Mechanical Properties of Biomedical Ti-Nb-Mo-Zr Alloys. Metals, 13(11), 1889. doi:10.3390/met13111889
  8. 7. Dumas, O., Malet, L., Kwaśniak, P., Prima, F., & Godet, S. (2023). Reorientation Induced Plasticity (RIP) in high-strength titanium alloys: An insight into the underlying mechanisms and resulting mechanical properties. Acta materialia, 246, 118679. doi:10.1016/j.actamat.2023.118679
  9. 8. Gabriel, S. S., de Holanda Ferrer, V., Rocha, A. D. C., Cossú, C. M. F. A. C., Nunes, A. R. V., Nunes, C., Malet, L., & de Almeida, L. H. (2022). Influence of Nb Addition on α″ and ω Phase Stability and on Mechanical Properties in the Ti-12Mo-xNb Stoichiometric System. Metals, 12(9), 1508. doi:10.3390/met12091508
  10. 9. Silveira, R. M. S. D. R., Guimarães, A. V., De Melo, C. H., Ribeiro, R. M., Farina, A. B., Malet, L., De Almeida, L. H., & Araújo, L. L. (2022). Effect of yttrium addition on phase transformations in alloy 718. Journal of International Research Publications: Materials, Methods & Technologies, 18, 3283-3290. doi:10.1016/j.jmrt.2022.03.137
  11. 10. Guzman, M. G., Arcos, M., Dille, J., Rousse, C., Godet, S., & Malet, L. (2021). Effect of the Concentration and the Type of Dispersant on the Synthesis of Copper Oxide Nanoparticles and Their Potential Antimicrobial Applications. ACS Omega, 6(29), 18576-18590. doi:10.1021/acsomega.1c00818
  12. 11. Dumas, O., Malet, L., Hary, B., Prima, F., & Godet, S. (2020). Crystallography and reorientation mechanism upon deformation in the martensite of an α-α’ Ti-6Al-4V dual-phase microstructure exhibiting high work-hardening rate. Acta materialia, 205, 116530. doi:10.1016/j.actamat.2020.116530
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