RAOELISON Rija Nirina

Dr. Rija RAOELISON is graduated with a BS degree in Mechanical Technology in 2004, and a MS degree in Mechanics-Materials-Processes in 2006, jointly accredited by Université Pierre et Marie Curie (Paris 6) and Ecole Normale Supérieure de Cachan. Graduated with a PhD degree of Engineering Science in 2010 and pursued postgraduate research for the development of the magnetic pulse welding process. Is a permanent associate professor at Université de Technologie de Belfort-Montbéliard (since 2013). His research activities are mainly on advanced manufacturing technology including cold spray additive manufacturing (fluid/powders interactions, CFD analysis, bulk manufacturing, solid state adhesion and additive phenomena, thermomechanical phenomena and simulation, process optimization, properties and applications), high-speed collision welding (metallurgical transformations under high-strain rate condition, characterization of structures, phases and properties; characterization, modelling and computational analysis of high strain-rate interfacial and bulk phenomena), and laser additive manufacturing (structures and properties, multiphysics modelling and simulation of metallurgical processes). Has been recently graduated with the accreditation « Habilitation à Diriger des Recherches » in process engineering, in december 2021 (dissertation entitled « Advancing the understanding on the optimization of emergent manufacturing methods based on a high-speed collision: cold spraying and magnetic pulse welding »). Has authored or co-authored over 100 publications including book chapters, peer-reviewed journal papers, peer-reviewed conference papers, invited speaker presentations, oral presentations, and poster presentations. Has supervised (including current research works) postgraduate works, PhD works, and Master internships. Has been a reviewer/jury member of PhD work defended in the field of Sciences & Engineering. Cited among the « 2022 World ranking Top 2% Scientists » list edited by Stanford University.

[1] R.N. Raoelison, Cold spray technology: a perspective of nature-inspired feature processing and biomanufacturing by a heatless additive method using nanopowders, in: A. Kumar, R.K. Mittal, A. Haleem (Eds.), Adv. Addit. Manuf. Artif. Intell. Nat.-Inspired Biomanufacturing, Elsevier, 2023: pp. 129–140. https://doi.org/10.1016/B978-0-323-91834-3.00003-X.

[2] H. Wu, R.N. Raoelison, Y. Zhang, S. Deng, H. Liao, Cold Spraying of 3D Parts – Challenges, in: Therm. Spray Coat., CRC Press, 2021.

[3] R.N. Raoelison, Coeval Cold Spray Additive Manufacturing Variances and Innovative Contributions, in: P. Cavaliere (Ed.), Cold-Spray Coat. Recent Trends Future Perspect., Springer International Publishing, Cham, 2018: pp. 57–94. https://doi.org/10.1007/978-3-319-67183-3_3.

[4] T. Sapanathan, R.N. Raoelison, N. Buiron, M. Rachik, Magnetic Pulse Welding: An Innovative Joining Technology for Similar and Dissimilar Metal Pairs, Join. Technol. (2016). https://doi.org/10.5772/63525.

[5] J. Xie, R.N. Raoelison, R. Di, Y. Liu, J. Li, M. Rachik, Laser remelting of AISI H13 tool steel: influence of cooling rate on the surface properties, Surf. Topogr. Metrol. Prop. 10 (2022) 044003. https://doi.org/10.1088/2051-672X/ac991c.

[6] J. Li, R.N. Raoelison, T. Sapanathan, M. Rachik, Determining the weldability window based on the interface morphologies formed during high-speed collision in magnetic pulse welding, Sci. Technol. Weld. Join. 0 (2022) 1–9. https://doi.org/10.1080/13621718.2022.2151733.

[7] L. Khoitara, R.N. Raoelison, S. Costil, 60% IACS Conductive Metal Coating on a Polymer Surface: Achievement of a Highly Efficient Additive Processing by Cold Spraying, Powders. 1 (2022) 262–272. https://doi.org/10.3390/powders1040018.

[8] X. Xie, S. Yin, R. Raoelison, C. Chen, C. Verdy, W. Li, G. Ji, Z. Ren, H. Liao, Al matrix composites fabricated by solid-state cold spray deposition: A critical review, J. Mater. Sci. Technol. 86 (2021) 20–55. https://doi.org/10.1016/j.jmst.2021.01.026.

[9] H. Wu, S. Liu, Y. Zhang, H. Liao, R.-N. Raoelison, S. Deng, New Process Implementation to Enhance Cold Spray-Based Additive Manufacturing, J. Therm. Spray Technol. (2021). https://doi.org/10.1007/s11666-021-01205-y.

[10] R.N. Raoelison, L. Lalu Koithara, S. Costil, Cold spray coating of PEEK surface by copper deposition: Interfacial adhesion at high deposition efficiency and bonding strength, CIRP J. Manuf. Sci. Technol. 35 (2021) 63–68. https://doi.org/10.1016/j.cirpj.2021.05.008.

[11] J.S. Li, T. Sapanathan, R.N. Raoelison, Y.L. Hou, A. Simar, M. Rachik, On the complete interface development of Al/Cu magnetic pulse welding via experimental characterizations and multiphysics numerical simulations, J. Mater. Process. Technol. (2021) 117185. https://doi.org/10.1016/j.jmatprotec.2021.117185.

[12] R.N. Raoelison, M.R. Guéchi, E. Padayodi, In-flight temperature of solid micrometric powders during cold spray additive manufacturing, Int. J. Therm. Sci. 157 (2020) 106422. https://doi.org/10.1016/j.ijthermalsci.2020.106422.

[13] R.N. Raoelison, L.L. Koithara, S. Costil, C. Langlade, Turbulences of the supersonic gas flow during cold spraying and their negative effects: A DNS CFD analysis coupled with experimental observation and laser impulse high-speed shadowgraphs of the particles in-flight flow, Int. J. Heat Mass Transf. 147 (2020) 118894. https://doi.org/10.1016/j.ijheatmasstransfer.2019.118894.

[14] J.S. Li, R.N. Raoelison, T. Sapanathan, Y.L. Hou, M. Rachik, Interface evolution during magnetic pulse welding under extremely high strain rate collision: mechanisms, thermomechanical kinetics and consequences, Acta Mater. 195 (2020) 404–415. https://doi.org/10.1016/j.actamat.2020.05.028.

[15] J.S. Li, R.N. Raoelison, T. Sapanathan, Z. Zhang, X.G. Chen, D. Marceau, Y.L. Hou, M. Rachik, An anomalous wave formation at the Al/Cu interface during magnetic pulse welding, Appl. Phys. Lett. 116 (2020) 161601. https://doi.org/10.1063/5.0005299.

[16] L.L. Koithara, R.N. Raoelison, S. Costil, X. Xie, High deposition efficiency and delamination issues during high-pressure cold spraying metallization of PEEK using spherical copper powders, Int. J. Adv. Manuf. Technol. (2020). https://doi.org/10.1007/s00170-020-05349-z.

[17] L.L. Koithara, R.N. Raoelison, S. Costil, Flow phenomenon of micron-sized particles during cold spray additive manufacturing: High-speed optic observation and characterization, Adv. Powder Technol. 31 (2020) 1060–1079. https://doi.org/10.1016/j.apt.2019.12.037.

[18] Y. Xie, C. Chen, R.N. Raoelison, M.-P. Planche, S. Deng, R. Huang, Z. Ren, H. Liao, Strengthened Peening Effect on Metallurgical Bonding Formation in Cold Spray Additive Manufacturing, J. Therm. Spray Technol. 28 (2019) 769–779. https://doi.org/10.1007/s11666-019-00854-4.

[19] R.N. Raoelison, J. Li, T. Sapanathan, E. Padayodi, N. Buiron, D. Racine, Z. Zhang, D. Marceau, M. Rachik, A new nature of microporous architecture with hierarchical porosity and membrane template via high strain rate collision, Materialia. 5 (2019) 100205. https://doi.org/10.1016/j.mtla.2018.100205.

[20] J. Li, R.N. Raoelison, T. Sapanathan, G. Racineux, M. Rachik, Assessing the influence of fieldshaper material on magnetic pulse welded interface of Al/Cu joints, Procedia Manuf. 29 (2019) 337–344. https://doi.org/10.1016/j.promfg.2019.02.146.

[21] J.S. Li, T. Sapanathan, R.N. Raoelison, Z. Zhang, X.G. Chen, D. Marceau, A. Simar, M. Rachik, Inverse prediction of local interface temperature during electromagnetic pulse welding via precipitate kinetics, Mater. Lett. 249 (2019) 177–179. https://doi.org/10.1016/j.matlet.2019.04.094.

[22] R.N. Raoelison, Y. Xie, T. Sapanathan, M.P. Planche, R. Kromer, S. Costil, C. Langlade, Cold gas dynamic spray technology: A comprehensive review of processing conditions for various technological developments till to date, Addit. Manuf. 19 (2018) 134–159. https://doi.org/10.1016/j.addma.2017.07.001.

[23] Y. Xie, M.-P. Planche, R. Raoelison, P. Hervé, X. Suo, P. He, H. Liao, Investigation on the influence of particle preheating temperature on bonding of cold-sprayed nickel coatings, Surf. Coat. Technol. 318 (2017) 99–105. https://doi.org/10.1016/j.surfcoat.2016.09.037.

[24] T. Sapanathan, K. Yang, D. Chernikov, R.N. Raoelison, V. Gluschenkov, N. Buiron, M. Rachik, Thermal Effect during Electromagnetic Pulse Welding Process, in: Mater. Sci. Forum, 2017: pp. 1662–1667. https://doi.org/10.4028/www.scientific.net/MSF.879.1662.

[25] T. Sapanathan, R.N. Raoelison, N. Buiron, M. Rachik, In situ metallic porous structure formation due to ultra high heating and cooling rates during an electromagnetic pulse welding, Scr. Mater. 128 (2017) 10–13. https://doi.org/10.1016/j.scriptamat.2016.09.030.

[26] R.N. Raoelison, Ch. Verdy, H. Liao, Cold gas dynamic spray additive manufacturing today: Deposit possibilities, technological solutions and viable applications, Mater. Des. 133 (2017) 266–287. https://doi.org/10.1016/j.matdes.2017.07.067.

[27] R.N. Raoelison, Analytical description of solid particles kinematics due to a fluid flow and application to the depiction of characteristic kinematics in cold spraying, Powder Technol. 319 (2017) 191–203. https://doi.org/10.1016/j.powtec.2017.06.029.

[28] Y. Xie, M.-P. Planche, R. Raoelison, H. Liao, X. Suo, P. Hervé, Effect of Substrate Preheating on Adhesive Strength of SS 316L Cold Spray Coatings, J. Therm. Spray Technol. 25 (2016) 123–130. https://doi.org/10.1007/s11666-015-0312-5.

[29] T. Sapanathan, R.N. Raoelison, K. Yang, N. Buiron, M. Rachik, Formation of porous inner architecture at the interface of magnetic pulse welded Al/Cu joints, AIP Conf. Proc. 1769 (2016) 100011. https://doi.org/10.1063/1.4963505.

[30] T. Sapanathan, R.N. Raoelison, E. Padayodi, N. Buiron, M. Rachik, Depiction of interfacial characteristic changes during impact welding using computational methods: Comparison between Arbitrary Lagrangian – Eulerian and Eulerian simulations, Mater. Des. 102 (2016) 303–312. https://doi.org/10.1016/j.matdes.2016.04.025.

[31] R.N. Raoelison, T. Sapanathan, E. Padayodi, N. Buiron, M. Rachik, Interfacial kinematics and governing mechanisms under the influence of high strain rate impact conditions: Numerical computations of experimental observations, J. Mech. Phys. Solids. 96 (2016) 147–161. https://doi.org/10.1016/j.jmps.2016.07.014.

[32] R.N. Raoelison, E. Aubignat, M.-P. Planche, S. Costil, C. Langlade, H. Liao, Low pressure cold spraying under 6bar pressure deposition: Exploration of high deposition efficiency solutions using a mathematical modelling, Surf. Coat. Technol. 302 (2016) 47–55. https://doi.org/10.1016/j.surfcoat.2016.05.068.

[33] R.N. Raoelison, T. Sapanathan, N. Buiron, M. Rachik, Magnetic pulse welding of Al/Al and Al/Cu metal pairs: Consequences of the dissimilar combination on the interfacial behavior during the welding process, J. Manuf. Process. 20 (2015) 112–127. https://doi.org/10.1016/j.jmapro.2015.09.003.

[34] R.N. Raoelison, D. Racine, Z. Zhang, N. Buiron, D. Marceau, M. Rachik, Magnetic pulse welding: Interface of Al/Cu joint and investigation of intermetallic formation effect on the weld features, J. Manuf. Process. 16 (2014) 427–434. https://doi.org/10.1016/j.jmapro.2014.05.002.

[35] R.N. Raoelison, A. Fuentes, C. Pouvreau, Ph. Rogeon, P. Carré, F. Dechalotte, Modeling and numerical simulation of the resistance spot welding of zinc coated steel sheets using rounded tip electrode: Analysis of required conditions, Appl. Math. Model. 38 (2014) 2505–2521. https://doi.org/10.1016/j.apm.2013.10.060.

[36] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, M. Habak, Study of the elaboration of a practical weldability window in magnetic pulse welding, J. Mater. Process. Technol. 213 (2013) 1348–1354. https://doi.org/10.1016/j.jmatprotec.2013.03.004.

[37] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Efficient welding conditions in magnetic pulse welding process, J. Manuf. Process. 14 (2012) 372–377. https://doi.org/10.1016/j.jmapro.2012.04.001.

[38] R. Raoelison, A. Fuentes, Ph. Rogeon, P. Carré, T. Loulou, D. Carron, F. Dechalotte, Contact conditions on nugget development during resistance spot welding of Zn coated steel sheets using rounded tip electrodes, J. Mater. Process. Technol. 212 (2012) 1663–1669. https://doi.org/10.1016/j.jmatprotec.2012.03.009.

[39] P. Rogeon, R. Raoelison, P. Carre, F. Dechalotte, A Microscopic Approach to Determine Electrothermal Contact Conditions During Resistance Spot Welding Process, J. Heat Transf. 131 (2009). https://doi.org/10.1115/1.3000596.

[40] T. Zhang, E. Padayodi, R.N. Raoelison, S. Khandar, W. Zaim-Mounajed, J.-C. Sagot, Investigation of the viability of cold spray coating of a sublayer-based CFRP composite, in: 29ème Colloq. Sci. Concept. Innov., Bâle, Suisse, 2022.

[41] T. Zhang, E. Padyyodi, R.-N. Raoelison, J.-C. Sagot, Sublayer-Assisted Cold Spray Metallization of Carbon Fiber Reinforced Composites, in: Int. Conf. Therm. Spray., ASM International, 2022: pp. 314–326. https://doi.org/10.31399/asm.cp.itsc2022p0314.

[42] T. Zhang, E. Padayodi, R.N. Raoelison, J.-C. Sagot, Development of Compatibilizing Sublayer for Metallizing CFRP Structures by Cold Spray, in: Int. Conf. Therm. Spray., ASM International, 2022: pp. 893–899. https://doi.org/10.31399/asm.cp.itsc2022p0893.

[43] W. Zaim-Mounajed, R. Raoelison N., T. Zhang, E. Padayodi, S. Khandar, A. Vashishtha, D. Callangan, C. Nolan, R. Raghavendra, J.-C. Sagot, Improvement of cold spray nozzle for an optimised deposition effeciency, in: 29ème Colloq. Sci. Concept. Innov., Bâle, Suisse, 2022.

[44] J. Xie, R.N. Raoelison, R. Di, Y. Liu, J. Li, M. Rachik, Effect of laser scanning velocity on the microstructural changes and mechanical properties of the H13 steel part treated by laser surface remelting, in: 6th Int. Conf. Adv. Solidif. Process., Le Bischenberg, France, 2022.

[45] J. Xie, R.N. Raoelison, M. Rachik, Segregation and oxidation phenomenon caused by Marangoni convection during the laser remelting of H13 steel, in: 15th Int. Conf. Adv. Comput. Eng. Exp., Italy, 2022.

[46] M. Sokore, H. Wu, W. Li, R. Raoelison N., S. Deng, H. Liao, Perspective of 3D Near-Net-Shape Additive Manufacturing by Cold Spraying: An Empirical Study Using Pure Al Powders, in: Int. Conf. Therm. Spray., Vienne, Autriche, 2022: pp. 306–313. https://doi.org/10.31399/asm.cp.itsc2022p0306.

[47] S. Khandar, R.N. Raoelison, E. Padayodi, T. Zhang, W. Zaim-Mounajed, J.-C. Sagot, Optimization on the sublayer embedded on CFRC for Cold Spray Metallization, in: 29ème Colloq. Sci. Concept. Innov., Bâle, Suisse, 2022.

[48] T. Zhang, E. Padayodi, R.N. Raoelison, J.-C. Sagot, Metallization of Fiber-Reinforced Polymer Composites via an in-situ sublayer and a cold spray deposition, in: 28ème Colloq. Sci. Concept. Innov., Saint-Malo, France, 2021.

[49] H. Wu, M. Sokore, W. Li, R. Rija Nirina, S. Deng, L. Hanlin, Toolpath Planning for Cold Spray Additive Manufacturing, in: 2nd Int. Conf. O Adv. Surf. Enhanc., Virtual conference, 2021.

[50] R.N. Raoelison, L.L. Koithara, S. Costil, Computational and Experimental Analysis of the Phenomenological Gas Flow Behavior and Particle Kinematics During Low Pressure Cold Spraying, in: Int. Conf. Therm. Spray., ASM International, 2021: pp. 229–234. https://doi.org/10.31399/asm.cp.itsc2021p0229.

[51] R. Kromer, R.N. Raoelison, Y. Danlos, C. Verdy, S. Costil, H. Liao, Adhesion Strength Improvement by Laser Surface Texturing of Metallic Repair Coatings Deposited by Cold Spraying, in: Int. Conf. Therm. Spray., ASM International, 2021: pp. 241–246. https://doi.org/10.31399/asm.cp.itsc2021p0241.

[52] J.S. Li, R.N. Raoelison, T. Sapanathan, M. Rachik, A predictive and reliable Eulerian model to compute the interface kinetics of magnetic pulse welding, in: NUMIFORM 2019 13th Int. Conf. Numer. Methods Ind. Form. Process., 2019: pp. 635–638.

[53] L.L. Koithara, R.N. Raoelison, S. Costil, X. Xiliang, Capability of cold spraying to obtain high deposition efficiency for the metallization of PEEK, in: Int. Conf. Therm. Spray., Japan, 2019: pp. 557–562.

[54] L.L. Koithara, R.N. Raoelison, S. Costil, M.P. Planche, Powder jet variations using Low Pressure Cold Spraying – for an improvement of the spraying yield, in: Int. Conf. Therm. Spray., Japan, 2019: pp. 9–14.

[55] K. Yang, T. Sapanathan, R.N. Raoelison, N. Buiron, M. Rachik, Fully coupled semi-analytical model for an electromagnetic-mechanical-thermal problem of a ring expansion test, in: 8th Int. Conf. High Speed Form. ICHSF 2018, 2018. http://dx.doi.org/10.17877/DE290R-18974.

[56] K. Yang, C. Dmitrii, T. Sapanathan, R.N. Raoelison, V. Gluschenkov, N. Buiron, M. Rachik, Heterogeneous deformation during electromagnetic ring expansion test, in: 7th Int. Conf. Coupled Probl. Sci. Eng. M Papadrakakis E Oñate B Schrefler Eds, 2017: pp. 514–522.

[57] Y. Xie, C. Chen, M.-P. Planche, R.N. Raoelison, Ch. Verdy, Hanlin Liao, Broken characteristics of the oxide film in cold spray, in: Int. Conf. Therm. Spray., USA, 2017: pp. 85–89.

[58] K. Yang, G. Taber, T. Sapanathan, A. Vivek, G.S. Daehn, R.N. Raoelison, N. Buiron, M. Rachik, Suitability of the electromagnetic ring expansion test to characterize materials under high strain rate deformation, MATEC Web Conf. 80 (2016) 15002. https://doi.org/10.1051/matecconf/20168015002.

[59] K. Yang, G. Taber, T. Sapanathan, A. Vivek, G.S. Daehn, R.N. Raoelison, N. Buiron, M. Rachik, Development of Vibration During the Electromagnetic Ring Expansion Test, in: 7th Int. Conf. High Speed Form., 2016: pp. 223–234. http://dx.doi.org/10.17877/DE290R-18974.

[60] K. Yang, T. Sapanathan, R.N. Raoelison, N. Buiron, M. Rachik, D. Jouaffre, Effect of conductivity of the inner rod on the collision conditions during a magnetic pulse welding process, in: 7th Int. Conf. High Speed Form., 2016: pp. 137–146. http://dx.doi.org/10.17877/DE290R-18974.

[61] Y. Xie, M.-P. Planche, R.N. Raoelison, H. Liao, P. Hervé, Influence of Substrate Temperature on Adhesive Strength of SS 316L Cold Spray Coatings – ASM International, in: Nternational Therm. Spray Conf., USA, 2015: pp. 825-830. https://www.asminternational.org/home/-/journal_content/56/10192/ZCP2015ITSC0825/CONFERENCE-PAPER (accessed October 31, 2019).

[62] R.N. Raoelison, M. Rachik, N. Buiron, D. Haye, M. Morel, B. Dos Santos, D. Jouaffre, G. Franz, Assessment of gap and charging voltage influence on mechanical behaviour of joints obtained by magnetic pulse welding, in: 5th Int. Conf. High Speed Form., Dortmund, Germany, 2012: pp. 207–216.

[63] R.N. Raoelison, N. Buiron, M. Habak, D. Haye, M. Rachik, Elastoplastic and Damage Behaviour of Magnetic Pulse Weld Interfaces, in: 10th Int. Conf. Technol. Plast., Aachen, Germany, 2010: pp. 1160–1163.

[64] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Modélisation du contact électrothermique – application au soudage par résistance par point, in: 14èmes Journ. Int. Therm., Tunisie, 2009.

[65] R.N. Raoelison, A. Fuentes, Ph. Rogeon, P. Carre, V. Robin, F. Dechalotte, Effect of Coating on Interfacial Conditions in Numerical Simulation of Resistance Spot, in: 5th Eur. Therm.-Sci. Conf. 2008, Editors G.G.M. Stoffels, Eindhoven, Netherland, 2008: p. 99.

[66] R.N. Raoelison, Ph. Rogeon, P. Carre, F. Dechalotte, G. Sibilia, Modélisation numérique du soudage par résistance par point d’assemblages symétriques de tôles revêtues à haute limite élastique, in: Actes Du13èmes Journ. Int. Therm. JITH, Albi, France, 2007: pp. 281–285.

[67] R.N. Raoelison, E. Padayodi, M.-R. Guechi, Caractérisation du champ thermique au sein des particules micrométriques soumises à un échange convectif pariétal lors de la fabrication additive par projection à froid., (2020). https://doi.org/10.25855/SFT2020-083.

[68] R.N. Raoelison, J. Li, T. Sapanathan, M. Rachik, Instabilités à forte vitesse de déformation lors de collisions balistiques en soudage par impact et conséquences structurales et thermomécaniques., (2020). https://doi.org/10.25855/SFT2020-064.

[69] R.N. Raoelison, L.L. Koithara, S. Costil, Phénomènes et régimes d’écoulement supersonique qui gouvernent la fabrication additive par projection à froid., (2020). https://doi.org/10.25855/SFT2020-065.

[70] R.N. Raoelison, C. Pouvreau, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Etude de l’influence des conditions interfaciales sur le développement du noyau lors du soudage par résistance par point, in: Giens, 2011. http://hal. archives-ouvertes. fr/docs/00/59/29/59/ANNEX/r_1280325L. pdf.

[71] K. Chaouch, R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Etude numérique de la soudabilité des assemblages dissymétriques lors du soudage par point, in: Actes Congrès Fr. Therm. SFT 2010, Le Touquet, 2010: pp. 767–772.

[72] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Modélisation des conditions interfaciales dans le cas du contact électro-thermique, in: Actes Congrès Fr. Therm. SFT 2008, Toulouse, 2009: pp. 1153–1158.

[73] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Effet du revêtement sur les conditions interfaciales lors du soudage par résistance par point de tôles revêtues, in: Actes Congrès Fr. Therm. SFT 2009, Vannes, 2009: pp. 565–570.

[74] R.N. Raoelison, Ph. Rogeon, P. Carre, S. Barbazanges, Caractérisation des conditions de contact électro-thermique lors du soudage par résistance par point des tôles revêtues, in: Actes Congrès Fr. Therm. SFT 2007, Les Embiez, 2007: pp. 1153–1158.

[75] T. Zhang, E. Padayodi, J.-C. Sagot, An experimental and computational analysis of cold spray metallization of CFRC structure: opportunities and issues, in: 10th RIPT Rencontre Int. Proj. Therm., Julich, Germany, 2022.

[76] T. Zhang, S. Khandar, R.N. Raoelison, E. Padayodi, J.-C. Sagot, Repair of a variety of CFRC structures using CS metallization: some perspectives, in: Cold Spray Club Meet., Milan, Italie, 2022.

[77] H. Wu, S. Liu, R.N. Raoelison, H. Liao, S. Deng, A fast and generic implementation method for thermal spraying: programming, processing and characterization, in: 10th RIPT Rencontre Int. Proj. Therm., Julich, Germany, 2022.

[78] M. Sokore, H. Wu, R.N. Raoelison, S. Deng, H. Liao, Properties characterization and heat treatment effects of aluminium 3D parts produced by Cold Sprayed Additive Manufacturing (CSAM), in: Int. Conf. Therm. Spray., Vienne, Autriche, 2022.

[79] M. Sokore, R.N. Raoelison, S. Msolli, S. Deng, H. Liao, Properties Characterization and Thermomechanical effects Investigation during Additive Growth of Cold- Sprayed thick Al1050 deposits., in: 10th RIPT Rencontre Int. Proj. Therm., Julich, Germany, 2022.

[80] M. Sokore, R.N. Raoelison, S. Deng, H. Liao, Numerical investigation of the thermomechanical stresses due to the high-speed collision in cold spray additive manufacturing, in: Int. Conf. Residual Stress., Nancy, France, 2022.

[81] R. Raoelison N., Modelling and simulation of the powder flow in cold spraying: focus on a factual dispersion phenomenon, in: 10th RIPT Rencontre Int. Proj. Therm., Julich, Germany, 2022.

[82] R.N. Raoelison, A. Vashishtha, S. Deng, D. Callangan, C. Nolan, R. Raghavendra, Powder deposition by Sub-millimeter Cold-spray Micro-Nozzle, in: 10th RIPT Rencontre Int. Proj. Therm., Julich, Germany, 2022.

[83] J. Li, R.N. Raoelison, T. Sapanathan, M. Rachik, A coupled thermal-mechanical model based on Eulerian formulation for magnetic pulse welding, in: Proceeding 8th Int. Conf. Coupled Probl. Sci. Eng., Spain, Barcelona, 2019. https://dial.uclouvain.be/pr/boreal/object/boreal:216704 (accessed October 23, 2019).

[84] J. Li, R.N. Raoelison, T. Sapanathan, M. Rachik, Experimental and numerical investigations of Al/Cu intermetallic layer resulting from magnetic pulse welding, in: 18th Int. Conf. Sheet Met. SHEMET 2019, Belgium, 2019.

[85] L.L. Koithara, R.N. Raoelison, S. Costil, Cold spraying as electrical functionalization of polymer substrate : achievements and limitations in case of copper deposition, in: Journ. Cold Spray Club Meet., Ecole des mines Paris, 2019.

[86] L.L. Koithara, R.N. Raoelison, S. Costil, X. Xiliang, Variance de jets de poudres lors de la fabrication additive à écoulement supersonique à basse pression et basse temperature : visualisation experimentale et simulation numérique, in: Conférence Matér. 2018, Strasbourg, 2018.

[87] L.L. Koithara, R.N. Raoelison, S. Costil, M.P. Planche, Fabrication additive des métaux par projection à froid basse pression: analyse du comportement phénoménologique de l’écoulement supersonique diphasique gas/poudres micrométriques, in: Conférence Matér. 2018, Strasbourg, 2018.

[88] T. Sapanathan, R.N. Raoelison, N. Buiron, M. Rachik, High velocity interfacial collision: Is it a potential method to produce a nanoporous surface?, in: 4th Int. Symp. Energy Chall. Mech. – Work. Small Scales, 2015. https://dial.uclouvain.be/pr/boreal/object/boreal:200982 (accessed October 31, 2019).

[89] T. Sapanathan, K. Yang, R.N. Raoelison, D. Jouaffre, N. Buiron, M. Rachik, Stress Analysis on the Inductor Parts During Electromagnetic Pulse Forming and Welding Processes Using Numerical Simulations, in: I2FG Impulse Form. Workshop 2014, Nantes, France, 2014.

[90] R.N. Raoelison, Z. Zhang, D. Racine, N. Buiron, D. Marceau, Magnetic pulse welding of dissimilar metals pairs: emerging issues on the weldability, in: 9th Int. Mater. Technol. Conf. Exhib. IMTCE 2014, Kuala Lampur, Malaysia, 2014.

[91] R.N. Raoelison, N. Buiron, M. Rachik, Interface structural analysis of similar and dissimilar magnetic pulse welded joints, in: I²FG Impulse Form. Workshop 2013, Belgium, 2013.

[92] R.N. Raoelison, N. Buiron, M. Rachik, La technologie par impulsion magnétique, in: Journ. Mise En Forme Assem. Compos., Compiègne, 2013.

[93] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Maîtrise du soudage par impulsion magnétique: application soudage, in: 6ème Édition Sem. Rech. L’Innovation En Picardie, Amiens, 2012.

[94] R.N. Raoelison, C. Pouvreau, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Etude de l’influence des conditions interfaciales sur le développement du noyau lors du soudage par résistance par point, in: Proceeding, Giens, France, 2011.

[95] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Maîtrise du soudage par impulsion magnétique : étude des conditions de soudage efficace, Innovation en soudage et brasage, in: Journ. SF2M, Ecole des Mines de Nancy, 2011.

[96] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Maîtrise du soudage par impulsion magnétique, in: 5ème Édition Sem. Rech. L’Innovation En Picardie, Saint-Quentin, 2011.

[97] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Procédés de soudage par résistance, problématiques autour des conditions aux interfaces, in: Journ. GIS BRESMAT Workshop, LIMatB Lorient, 2010.

[98] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Maîtrise du soudage par impulsion magnétique, in: 4ème Édition Sem. Rech. L’Innovation En Picardie, Compiègne, 2010.

[99] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Modélisation du contact électrothermique dans le cadre du soudage résistif, in: Programme Pluri-Form. ‘Couplage Multi Phys. À Haute Température, LTDS ENI Saint Etienne, 2008.

[100] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, A. Fuentes, Etude et modélisation des effets du revêtement sur les conditions interfaciales lors du soudage par point des tôles revêtues, in: Journ. Thématique SFT Modélisation Therm. Trait. Matér., LTm IUT Le Creusot, 2008.

[101] R.N. Raoelison, Ph. Rogeon, P. Carre, A. Fuentes, Modélisation des effets du revêtement de zinc sur les conditions de contact en soudage par résistance par point, in: Programme Pluri-Form. ‘Couplage Multi Phys. À Haute Température, LTDS ENI Saint Etienne, 2007.

[102] A. Fuentes, R.N. Raoelison, Ph. Rogeon, P. Carre, S. Barbazanges, Prédiction numérique de la soudabilité opératoire d’assemblage de tôles revêtues par soudage résistif, in: Journ. SF2M Ouest, Brest, 2007.

Convective heat transfer and CFD (Lecture, tutorial classes)

Design for environment (Lecture, tutorial classes)

Finite element method and computational analysis (Lecture, tutorial classes)

Design and dimensioning of structures (Lecture, tutorial classes)

Fluid Mechanics (Tutorial classes)

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rija-nirina.raoelison@utbm.fr

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Univ. Bourgogne Franche Comté (UBFC)

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Dr. Rija RAOELISON is graduated with a BS degree in Mechanical Technology in 2004, and a MS degree in Mechanics-Materials-Processes in 2006, jointly accredited by Université Pierre et Marie Curie (Paris 6) and Ecole Normale Supérieure de Cachan. Graduated with a PhD degree of Engineering Science in 2010 and pursued postgraduate research for the development of the magnetic pulse welding process. Is a "Maître de conférences" (permanent associate professor) at Université de Technologie de Belfort-Montbéliard (since 2013). His research activities are mainly on advanced manufacturing technology including cold spray additive manufacturing (fluid/powders interactions, CFD analysis, bulk manufacturing, solid state adhesion additive phenomena, thermomechanical phenomena and simulation, process optimization, properties and applications), high-speed collision welding (metallurgical transformations under high-strain rate condition, characterization of structures, phases and properties; characterization, modelling and computational analysis of high strain-rate interfacial and bulk phenomena), and laser additive manufacturing (structures and properties, multiphysics modelling and simulation of metallurgical processes). Has been recently graduated with the accreditation "Habilitation à Diriger des Recherches" in process engineering, in december 2021 (dissertation entitled "Advancing the understanding on the optimization of emergent manufacturing methods based on a high-speed collision: cold spraying and magnetic pulse welding"). Cited among the "2022 Worldwide Top 2% Scientists" identified by Stanford University.

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Dr. Rija RAOELISON is graduated with a BS degree in Mechanical Technology in 2004, and a MS degree in Mechanics-Materials-Processes in 2006, jointly accredited by Université Pierre et Marie Curie (Paris 6) and Ecole Normale Supérieure de Cachan. Graduated with a PhD degree of Engineering Science in 2010 and pursued postgraduate research for the development of the magnetic pulse welding process. Is a permanent associate professor at Université de Technologie de Belfort-Montbéliard (since 2013). His research activities are mainly on advanced manufacturing technology including cold spray additive manufacturing (fluid/powders interactions, CFD analysis, bulk manufacturing, solid state adhesion and additive phenomena, thermomechanical phenomena and simulation, process optimization, properties and applications), high-speed collision welding (metallurgical transformations under high-strain rate condition, characterization of structures, phases and properties; characterization, modelling and computational analysis of high strain-rate interfacial and bulk phenomena), and laser additive manufacturing (structures and properties, multiphysics modelling and simulation of metallurgical processes). Has been recently graduated with the accreditation "Habilitation à Diriger des Recherches" in process engineering, in december 2021 (dissertation entitled "Advancing the understanding on the optimization of emergent manufacturing methods based on a high-speed collision: cold spraying and magnetic pulse welding"). Has authored or co-authored over 100 publications including book chapters, peer-reviewed journal papers, peer-reviewed conference papers, invited speaker presentations, oral presentations, and poster presentations. Has supervised (including current research works) postgraduate works, PhD works, and Master internships. Has been a reviewer/jury member of PhD work defended in the field of Sciences & Engineering. Cited among the "2022 World ranking Top 2% Scientists" list edited by Stanford University.

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[2] H. Wu, R.N. Raoelison, Y. Zhang, S. Deng, H. Liao, Cold Spraying of 3D Parts – Challenges, in: Therm. Spray Coat., CRC Press, 2021.

[30] T. Sapanathan, R.N. Raoelison, E. Padayodi, N. Buiron, M. Rachik, Depiction of interfacial characteristic changes during impact welding using computational methods: Comparison between Arbitrary Lagrangian - Eulerian and Eulerian simulations, Mater. Des. 102 (2016) 303–312. https://doi.org/10.1016/j.matdes.2016.04.025.

[49] H. Wu, M. Sokore, W. Li, R. Rija Nirina, S. Deng, L. Hanlin, Toolpath Planning for Cold Spray Additive Manufacturing, in: 2nd Int. Conf. O Adv. Surf. Enhanc., Virtual conference, 2021.

[57] Y. Xie, C. Chen, M.-P. Planche, R.N. Raoelison, Ch. Verdy, Hanlin Liao, Broken characteristics of the oxide film in cold spray, in: Int. Conf. Therm. Spray., USA, 2017: pp. 85–89.

[61] Y. Xie, M.-P. Planche, R.N. Raoelison, H. Liao, P. Hervé, Influence of Substrate Temperature on Adhesive Strength of SS 316L Cold Spray Coatings - ASM International, in: Nternational Therm. Spray Conf., USA, 2015: pp. 825-830. https://www.asminternational.org/home/-/journal_content/56/10192/ZCP2015ITSC0825/CONFERENCE-PAPER (accessed October 31, 2019).

[64] R.N. Raoelison, Ph. Rogeon, P. Carre, T. Loulou, F. Dechalotte, Modélisation du contact électrothermique - application au soudage par résistance par point, in: 14èmes Journ. Int. Therm., Tunisie, 2009.

[76] T. Zhang, S. Khandar, R.N. Raoelison, E. Padayodi, J.-C. Sagot, Repair of a variety of CFRC structures using CS metallization: some perspectives, in: Cold Spray Club Meet., Milan, Italie, 2022.

[81] R. Raoelison N., Modelling and simulation of the powder flow in cold spraying: focus on a factual dispersion phenomenon, in: 10th RIPT Rencontre Int. Proj. Therm., Julich, Germany, 2022.

[91] R.N. Raoelison, N. Buiron, M. Rachik, Interface structural analysis of similar and dissimilar magnetic pulse welded joints, in: I²FG Impulse Form. Workshop 2013, Belgium, 2013.

[92] R.N. Raoelison, N. Buiron, M. Rachik, La technologie par impulsion magnétique, in: Journ. Mise En Forme Assem. Compos., Compiègne, 2013.

[96] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Maîtrise du soudage par impulsion magnétique, in: 5ème Édition Sem. Rech. L’Innovation En Picardie, Saint-Quentin, 2011.

[98] R.N. Raoelison, N. Buiron, M. Rachik, D. Haye, G. Franz, Maîtrise du soudage par impulsion magnétique, in: 4ème Édition Sem. Rech. L’Innovation En Picardie, Compiègne, 2010.

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Convective heat transfer and CFD (Lecture, tutorial classes)

Design for environment (Lecture, tutorial classes)

Finite element method and computational analysis (Lecture, tutorial classes)

Design and dimensioning of structures (Lecture, tutorial classes)

Fluid Mechanics (Tutorial classes)

[/kc_column_text][/kc_tab][/kc_tabs][/kc_column][/kc_row]

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