Commin, L., Dumont, M., Masse, J.-E. & Barrallier, L. Friction stir welding of AZ31 magnesium alloy rolled sheets: Influence of processing parameter. Acta Mater. 57, 326334 (2009).<\/p>\n
ADS CAS Article Google Scholar <\/p>\n
Joshi, S. S., Mohan, M., Seshan, S., Kumar, S. & Suwas, S. Effect of addition of Al & Ca and heat treatment on the cast Mg-6Zn alloy. Mater. Sci. Forum 765, 3337 (2013).<\/p>\n
Article Google Scholar <\/p>\n
Shrikant, J.S. Development of cast magnesium alloys with improved strength. Masters thesis (2014).<\/p>\n
Kulekci, M. K. Magnesium and its alloys applications in automotive industry. Int. J. Adv. Manuf. Technol. 39, 851865 (2008).<\/p>\n
Article Google Scholar <\/p>\n
Bagheri, B., Abbasi, M., Abdollahzadeh, A. & Mirsalehi, S. E. Effect of second-phase particle size and presence of vibration on az91\/sic surface composite layer produced by fsp. Trans. Nonferrous Metals Soc. China 30, 905916 (2020).<\/p>\n
CAS Article Google Scholar <\/p>\n
Wu, T.-C. et al. Microstructure and surface texture driven improvement in in-vitro response of laser surface processed AZ31B magnesium alloy. J. Magnes. Alloys 9, 14061418 (2021).<\/p>\n
CAS Article Google Scholar <\/p>\n
Dahotre, N. B. & Joshi, S. Machining of Bone and Hard Tissues (Springer, Cham, Switzerland, 2016).<\/p>\n
Book Google Scholar <\/p>\n
Aghion, E. et al. The art of developing new magnesium alloys for high temperature applications. Mater. Sci. Forum 419, 407418 (2003).<\/p>\n
Article Google Scholar <\/p>\n
Aghion, E. & Bronfin, B. Magnesium alloys development towards the 21(^{st}) century. Mater. Sci. Forum 350, 1930 (2000).<\/p>\n
Article Google Scholar <\/p>\n
Karunakaran, R., Ortgies, S., Tamayol, A., Bobaru, F. & Sealy, M. P. Additive manufacturing of magnesium alloys. Bioact. Mater. 5, 4454 (2020).<\/p>\n
Article Google Scholar <\/p>\n
Br, F. et al. Laser additive manufacturing of biodegradable magnesium alloy WE43: A detailed microstructure analysis. Acta Biomater. 98, 3649 (2019).<\/p>\n
Article Google Scholar <\/p>\n
Holguin, D. A. M., Han, S. & Kim, N. P. Magnesium alloy 3D printing by wire and arc additive manufacturing (WAAM). MRS Adv. 3, 29592964 (2018).<\/p>\n
Article Google Scholar <\/p>\n
Yu, H. Z. & Mishra, R. S. Additive friction stir deposition: A deformation processing route to metal additive manufacturing. Mater. Res. Lett. 9, 7183 (2021).<\/p>\n
CAS Article Google Scholar <\/p>\n
Angelo, P. & Subramanian, R. Powder Metallurgy: Science, Technology and Applications (PHI Learning Pvt. Ltd., New Delhi, 2008).<\/p>\n
Google Scholar <\/p>\n
Gradl, P., Mireles, O. & Andrews, N. Intro to additive manufacturing for propulsion systems. In AIAA Joint Propulsion Conference (2018).<\/p>\n
Singh, U., Lohumi, M. & Kumar, H. Additive manufacturing in wind energy systems: A review. In Proceedings of International Conference in Mechanical and Energy Technology 757766 (Springer, 2020).<\/p>\n
Asiatico, P.M. The applicability of additive friction stir deposition for bridge repair. Masters thesis, Virginia Tech (2021).<\/p>\n
Garcia, D. et al. In situ investigation into temperature evolution and heat generation during additive friction stir deposition: A comparative study of Cu and Al-Mg-Si. Addit. Manuf. 34, 101386 (2020).<\/p>\n
CAS Google Scholar <\/p>\n
Perry, M. E. et al. Tracing plastic deformation path and concurrent grain refinement during additive friction stir deposition. Materialia 18, 101159 (2021).<\/p>\n
CAS Article Google Scholar <\/p>\n
Griffiths, R. J. et al. A perspective on solid-state additive manufacturing of aluminum matrix composites using MELD. J. Mater. Eng. Perform. 28, 648656 (2019).<\/p>\n
CAS Article Google Scholar <\/p>\n
Calvert, J.R. Microstructure and mechanical properties of WE43 alloy produced via additive friction stir technology. Masters thesis, Virginia Tech (2015).<\/p>\n
Robinson, T.W. etal. Microstructural and mechanical properties of a solid-state additive manufactured magnesium alloy. J. Manuf. Sci. Eng. 144 (2022).<\/p>\n
Williams, M. et al. Elucidating the effect of additive friction stir deposition on the resulting microstructure and mechanical properties of magnesium alloy we43. Metals 11, 1739 (2021).<\/p>\n
CAS Article Google Scholar <\/p>\n
Schmidt, H. B. & Hattel, J. H. Thermal modelling of friction stir welding. Scr. Mater. 58, 332337. https:\/\/doi.org\/10.1016\/j.scriptamat.2007.10.008<\/a> (2008).<\/p>\n CAS Article Google Scholar <\/p>\n Schmidt, H. & Hattel, J. Modelling heat flow around tool probe in friction stir welding. Sci. Technol. Weld. Join. 10, 176186. https:\/\/doi.org\/10.1179\/174329305X36070<\/a> (2005).<\/p>\n Article Google Scholar <\/p>\n Zhai, M., Wu, C. S. & Su, H. Influence of tool tilt angle on heat transfer and material flow in friction stir welding. J. Manuf. Process. 59, 98112. https:\/\/doi.org\/10.1016\/j.jmapro.2020.09.038<\/a> (2020).<\/p>\n Article Google Scholar <\/p>\n Liu, Q., Han, R., Gao, Y. & Ke, L. Numerical investigation on thermo-mechanical and material flow characteristics in friction stir welding for aluminum profile joint. Int. J. Adv. Manuf. Technol. 114, 24572469. https:\/\/doi.org\/10.1007\/s00170-021-06978-8<\/a> (2021).<\/p>\n Article Google Scholar <\/p>\n Stubblefield, G. G., Fraser, K., Phillips, B. J., Jordon, J. B. & Allison, P. G. A meshfree computational framework for the numerical simulation of the solid-state additive manufacturing process, additive friction stir-deposition (AFS-D). Mater. Des.https:\/\/doi.org\/10.1016\/j.matdes.2021.109514<\/a> (2021).<\/p>\n Article Google Scholar <\/p>\n Samant, A. N., Du, B., Paital, S. R., Kumar, S. & Dahotre, N. B. Pulsed laser surface treatment of magnesium alloy: Correlation between thermal model and experimental observations. J. Mater. Process. Technol. 209, 50605067 (2009).<\/p>\n CAS Article Google Scholar <\/p>\n Santhanakrishnan, S. et al. Macro-and microstructural studies of laser-processed WE43 (Mg-Y-Nd) magnesium alloy. Metall. Mater. Trans. B 44, 11901200 (2013).<\/p>\n CAS Article Google Scholar <\/p>\n Ho, Y.-H., Vora, H. D. & Dahotre, N. B. Laser surface modification of AZ31B Mg alloy for bio-wettability. J. Biomater. Appl. 29, 915928 (2015).<\/p>\n Article Google Scholar <\/p>\n Wu, T.-C., Ho, Y.-H., Joshi, S. S., Rajamure, R. S. & Dahotre, N. B. Microstructure and corrosion behavior of laser surface-treated AZ31B Mg bio-implant material. Lasers Med. Sci. 32, 797803 (2017).<\/p>\n Article Google Scholar <\/p>\n Lu, J. Z. et al. Optimization of biocompatibility in a laser surface treated Mg-AZ31B alloy. Mater. Sci. Eng. C 105, 110028 (2019).<\/p>\n CAS Article Google Scholar <\/p>\n Kalakuntla, N. et al. Laser patterned hydroxyapatite surfaces on AZ31b magnesium alloy for consumable implant applications. Materialia 11, 100693 (2020).<\/p>\n CAS Article Google Scholar <\/p>\n Ho, Y.-H. et al. In-vitro bio-corrosion behavior of friction stir additively manufactured AZ31B magnesium alloy-hydroxyapatite composites. Mater. Sci. Eng. C 109, 110632 (2020).<\/p>\n CAS Article Google Scholar <\/p>\n Ho, Y.-H. et al. In-vitro biomineralization and biocompatibility of friction stir additively manufactured AZ31B magnesium alloy-hydroxyapatite composites. Bioact. Mater. 5, 891901 (2020).<\/p>\n Article Google Scholar <\/p>\n Joshi, S. S. et al. Additive Friction stir deposition of AZ31B magnesium alloy. J. Magnes. Alloyshttps:\/\/doi.org\/10.1016\/j.jma.2022.03.011 (2022).<\/p>\n Article Google Scholar <\/p>\n Avedesian, M. M. et al. ASM Specialty Handbook: Magnesium and Magnesium Alloys (ASM International, Materials Park, OH, 1999).<\/p>\n Google Scholar <\/p>\n Riahi, M. & Nazari, H. Analysis of transient temperature and residual thermal stresses in friction stir welding of aluminum alloy 6061T6 via numerical simulation. Int. J. Adv. Manuf. Technol. 55, 143152 (2011).<\/p>\n Article Google Scholar <\/p>\n Zhang, Z. et al. Experimental and numerical studies of re-stirring and re-heating effects on mechanical properties in friction stir additive manufacturing. Int. J. Adv. Manuf. Technol. 104, 767784 (2019).<\/p>\n Article Google Scholar <\/p>\n Singh, A. K., Sahlot, P., Paliwal, M. & Arora, A. Heat transfer modeling of dissimilar FSW of Al 6061\/AZ31 using experimentally measured thermo-physical properties. Int. J. Adv. Manuf. Technol. 105, 771783 (2019).<\/p>\n Article Google Scholar <\/p>\n B962, A. Standard test methods for density of compacted or sintered powder metallurgy (pm) products using archimedes principle. Annual Book of ASTM Standards. ASTM (2001).<\/p>\n Pantawane, M. V. et al. Thermomechanically influenced dynamic elastic constants of laser powder bed fusion additively manufactured Ti6Al4V. Mater. Sci. Eng. A 811, 140990. https:\/\/doi.org\/10.1016\/J.MSEA.2021.140990<\/a> (2021).<\/p>\n CAS Article Google Scholar <\/p>\n Pantawane, M. V. et al. Crystallographic texture dependent bulk anisotropic elastic response of additively manufactured Ti6Al4V. Sci. Rep. 11, 110. https:\/\/doi.org\/10.1038\/s41598-020-80710-6<\/a> (2021).<\/p>\n CAS Article Google Scholar <\/p>\n ASTM, E. etal. Standard test methods for tension testing of metallic materials. Annual Book of ASTM Standards. ASTM (2001).<\/p>\n Meyghani, B. & Wu, C. Progress in thermomechanical analysis of friction stir welding. Chin. J. Mech. Eng. (English Edition)https:\/\/doi.org\/10.1186\/s10033-020-0434-7 (2020).<\/p>\n Article Google Scholar <\/p>\n Colegrove, P. A., Shercliff, H. R. & Zettler, R. Model for predicting heat generation and temperature in friction stir welding from the material properties. Sci. Technol. Weld. Join. 12, 284297. https:\/\/doi.org\/10.1179\/174329307X197539<\/a> (2007).<\/p>\n CAS Article Google Scholar <\/p>\n Schmidt, H., Hattel, J. & Wert, J. An analytical model for the heat generation in friction stir welding. Modell. Simul. Mater. Sci. Eng. 12, 143157. https:\/\/doi.org\/10.1088\/0965-0393\/12\/1\/013<\/a> (2004).<\/p>\n ADS Article Google Scholar <\/p>\n Nandan, R., Roy, G. G. & Debroy, T. Numerical simulation of three dimensional heat transfer and plastic flow during friction stir welding. Metall. Mater. Trans. A 37, 12471259. https:\/\/doi.org\/10.1007\/s11661-006-1076-9<\/a> (2006).<\/p>\n Article Google Scholar <\/p>\n Nartu, M. et al. Omega versus alpha precipitation mediated by process parameters in additively manufactured high strength Ti-1Al-8V-5Fe alloy and its impact on mechanical properties. Mater. Sci. Eng. A 821, 141627. https:\/\/doi.org\/10.1016\/J.MSEA.2021.141627<\/a> (2021).<\/p>\n CAS Article Google Scholar <\/p>\n Joshi, S. S., Sharma, S., Mazumder, S., Pantawane, M. V. & Dahotre, N. B. Solidification and microstructure evolution in additively manufactured H13 steel via directed energy deposition: Integrated experimental and computational approach. J. Manuf. Process. 68, 852866. https:\/\/doi.org\/10.1016\/J.JMAPRO.2021.06.009<\/a> (2021).<\/p>\n Article Google Scholar <\/p>\n Antoniswamy, A.R., Carter, J.T., Hector, L.G. & Taleff, E.M. Static recrystallization and grain growth in az31b-h24 magnesium alloy sheet. In Magnesium Technology 2014 139142 (Springer, 2014).<\/p>\n Okamoto, H. & Okamoto, H. Phase Diagrams for Binary Alloys Vol. 44 (ASM International, Materials Park, OH, 2000).<\/p>\n MATH Google Scholar <\/p>\n Sepehrband, P., Lee, M. & Burns, A. Pre-straining effect on precipitation behaviour of AZ31B. In Magnesium Technology 2016 8992 (Springer, 2016).<\/p>\n Wong, T. W., Hadadzadeh, A., Benoit, M. J. & Wells, M. A. Impact of homogenization heat treatment on the high temperature deformation behavior of cast az31b magnesium alloy. J. Mater. Process. Technol. 254, 238247 (2018).<\/p>\n CAS Article Google Scholar <\/p>\n <\/p>\n The rest is here: <\/p>\n A multi modal approach to microstructure evolution and mechanical response of additive friction stir deposited AZ31B Mg alloy | Scientific Reports -...<\/a><\/p>\n","protected":false},"excerpt":{"rendered":" Commin, L., Dumont, M., Masse, J.-E. & Barrallier, L. Friction stir welding of AZ31 magnesium alloy rolled sheets: Influence of processing parameter. Continue reading