A D V A N C E D M A T E R I A L S & P R O C E S S E S | A P R I L 2 0 2 3 2 7 AM practices that can be used for manufacturing ceramics and ceramic- based composites. SL and different associated techniques offer the possibility of producing ceramic components with finer resolution. Powder-based techniques like binder jetting and indirect SLS can be used for designing porous ceramics. SLM offers practitioners the option of manufacturing ceramics with minimal post-processing requirements, though further research is needed to decrease the cost of materials processing by SLM. ~AM&P Note: PureAir is a registered trademark of Pure Air Filtration LLC. For more information: Surojit Gupta, associate professor, Department of Mechanical Engineering, University of North Dakota, 243 Centennial Drive Stop 8359, Grand Forks, ND 58202, 701.777.1632, surojit.gupta@und.edu. References 1. J.L. Amoros, et al., Green Strength Testing of Pressed Compacts: An Analysis of the Different Methods, J. Eur. Ceram. Soc., 28, p 701-710, 2008. 2. J.B. Dahmus, et al., An Environmental Analysis of Machining, Proceedings of the ASME International Mechanical Engineering Congress and RD&D Expo, Nov. 13-19, 2004. 3. What is a Circular Economy, Ellen MacArthur Foundation, Feb. 2023, https://www.ellenmacarthurfoundation.org/circular-economy/concept. 4. M. Despeisse, et al., Unlocking Value for a Circular Economy through 3D Printing: A Research Agenda, Technological Forecasting and Social Change, 115, p 75-84, Feb. 2017. 5. ASTM F2792-12a: Standard Terminology for Additive Manufacturing Technologies, ASTM International, West Conshohocken, PA, 2012. 6. G. Ingarao, et al., A Comparative Assessment of Energy Demand and Life Cycle Costs forAdditive-andSubtractivebased Manufacturing Approaches, J. of Mfg. Proc., 56, p 1219-1229, 2020. 7. T. Gutowski, et al., Note on the Rate and Energy Efficiency Limits for Additive Manufacturing, J. Ind Ecol., 21 (S1), p S69-S79, 2017. 8. Z. Chen, et al., 3D Printing of Ceramics: A Review, J. Eur. Cer. Soc., 39, p 661-687, 2019. 9. R.P. Chaudhary, et al., Additive Manufacturing of Polymer-derived Ceramics: Materials, Technologies, Properties and Potential Applications, Prog. in Mat. Sci., 128, p 100969, 2022. 10. J.W. Halloran, Ceramic Stereo- lithography: Additive Manufacturing for Ceramics by Photopolymerization, Annu. Rev. Mater. Res., 46, p 19-40, 2016. 11. R. Dunnigan, et al., Beneficial Usage of Recycled Polymer Particulates for DesigningNovel 3DPrintedComposites, Prog. Addit. Manuf., 3, p 33-38, 2018. 12. M. Schwentenwein, et al., Additive Manufacturing of Dense Alumina Ceramics, Int. J. Appl. Ceram. Technol., 12, p 1-7, 2015. 13. M. Lee, et al., Development of a 3D Printer using Scanning Projection Stereolithography, Sci. Rep., 5, p 9875, 2015. 14. K.S. Lee, et al., Advances in3DNano/ Microfabrication using Two-photon Initiated Polymerization, Prog. Polym. Sci., 33, p 631-681, 2008. 15. B. Derby, Inkjet Printing of Functional and Structural Materials: Fluid Property Requirements, Feature Stability, and Resolution, Annu. Rev. Mater. Res., 40, p 395-414, 2010. 16. B. Derby, Additive Manufacture of Ceramics Components by Inkjet Printing, Eng., 1, p 113-123, 2015. 17. E. Peng, et al., CeramicRobocasting: Recent Achievements, Potential, and Future Developments, Adv. Mat., 30, 2018. 18. E.M. Sachs, Three-dimensional Printing Techniques, United States Patent No. 5,204,055, 1993. 19. X. Ly, Binder Jetting of Ceramics: Powders, Binders, Printing Parameters, Equipment, and Post-treatment, Cer. Int., 45, p 12609-12624, 2019. 20. J.J. Beaman, et al., Selective Laser Sintering with Assisted Powder Handling, United States Patent No. 4,938,816, 1990. 21. X. Zhang, et al., Additive Manufacturing of Zirconia Ceramics: A State-of-the-Art Review, J. of Mat. Res. Tech., 9, p 9029-9048, 2020. 22. W. Meiners, et al., Selective Laser Sintering at Melting Temperature, United States Patent No. 6,215,093 B1, 2001. 23. A. Gahler, et al., Direct Laser Sintering of Al2O3–SiO2 Dental Ceramic Components by Layer-wise Slurry Deposition, J. Amer. Cer. Soc., 89, p 3076-3080, 2016. 24. H. Yves-Christian, et al., Net Shaped High Performance Oxide Ceramic Parts by Selective Laser Melting, Phys. Procedia, 5, p 587-594, 2010. 25. Y. Li, et al., Additive Manufacturing of Alumina using Laser Engineered Net Shaping: Effects of Deposition Variables, Cer. Int., 43, p 7768-7775, 2017. 26. Y. Hu, et al., Ultrasonic Vibrationassisted Laser Engineering Net Shaping of ZrO2-Al2O3 Bulk Parts: Effects on Crack Suppression, Microstructure, and Mechanical Properties, Cer. Int., 44, p 2752-2760, 2018. 27. W.J. Sames, et al., The Metallurgy and Processing Science of Metal Additive Manufacturing, Int. Mat. Rev., 61, 5, p 315–60, 2016. 28. A.H. Hocker et al., The Printability of Ternary Metal Boride (MAB) Materials using Laser Powder Bed Fusion, MS&T’21, Oct. 17-20, 2021.
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