UC Riverside UC Riverside Electronic Theses and Dissertations Title Development of Co-Ni-Ga Ferromagnetic Shape Memory Alloys (FSMAs) by Investigating the Effects of Solidification Processing Parameters Permalink https://escholarship.org/uc/item/4tj615d9 Author Kalaantari, Haamun Publication Date 2013 Peer reviewed|Thesis/dissertation eScholarship.org Powered by the California Digital Library University of California UNIVERSITY OF CALIFORNIA RIVERSIDE Development of Co-Ni-Ga Ferromagnetic Shape Memory Alloys (FSMAs) by Investigating the Effects of Solidification Processing Parameters A Dissertation submitted in partial satisfaction of the requirements for the degree of Doctor of Philosophy in Mechanical Engineering by Haamun Kalaantari March 2013 Dissertation Committee: Professor Reza Abbaschian, Chairperson Professor Cengiz Ozkan Professor Javier Garay Copyright by Haamun Kalaantari 2013 The Dissertation of Haamun Kalaantari is approved: Committee Chairperson University of California, Riverside Acknowledgments I wish to take this opportunity and express my appreciation and respect to all of them who made my journey unforgettable to this point. First and the foremost, I am deeply indebted and thankful to my PhD advisor, Professor Reza Abbaschian for all of his enlightening guidance, unreserved support, kindness, generosity, motivation, enthusiasm and the confidence he gave me through each single step of this journey. He taught me a lot through those numerous research and stimulating discussions and provided me with constructive suggestions. His mentorship was paramount in providing a well-rounded experience consistent with my long-term career goals. I have been amazingly fortunate to have an advisor who gave me the freedom to explore on my own, and at the same time the guidance to recover when my steps faltered. His patience and support helped me overcome many crises and finish this dissertation. He encouraged me to grow not only as an experimentalist but also as an instructor and an independent thinker. I am not sure many graduate students are given the opportunity to develop their own individuality and self-sufficiency by being allowed to work with such independence. For everything you have done for me, Professor Abbaschian, I thank you. My thanks also go to the members of my internal dissertation committee, Professor Cengiz Ozkan and Professor Javier Garay for reading the research proposal and previous drafts of this dissertation and providing valuable comments that improved the presentation and contents of this dissertation. iv I would like to thank Dr. Abraham Munitz for his kindness and help in putting together our Electromagnetic Levitation system parts and performing early experiments in our lab at University of California, Riverside. My gratitude is also extended to Professor Sakhrat Khizroev and his colleagues Dr. Nissim Amos and Dr. Jeongmin Hong at the Center for 3D Electronics within the Department of Electrical Engineering for helping me with magnetic characterization experiments and VSM measurements. I am truly thankful to all my friends, colleagues and staff in the Department of Mechanical Engineering at UC Riverside specially Shaahin Amini, Melina Roshandell, Jun Wang, Roseanna Baron-Lopez, Terry Traver, Katie Dell, Paul Talavera, Sarah Nosce, Jennifer Morgan, and Becki Jo Ray and Eilene Montoya in the Dean’s office for their unconditional help and support during these years. None of this would have been possible without the endless love and patience of my family. I am really indebted and deeply thankful to my parents, Mohammad Amir and Nezhat for their faith in me and allowing me to be as ambitious as I wanted. It was under their watchful eye that I gained so much drive and an ability to tackle challenges head on. My sisters Leila and Zahra have been a constant source of love, concern, support and strength all these years. I would like also to express my heart-felt gratitude to my all extended-family members. v And last, but not the least, I warmly appreciate the generosity and understanding of my lovely wife, Fatemeh, who supported me spiritually from the first day of our common life and never left me alone with this journey until the last day. Haamun Kalaantari Riverside March 2013 vi To my all wonderful teachers who believe in diligence, science and pursuit of academic excellence. Particularly, to my very first teachers, my mom Nezhat and my dad Mohammad Amir vii ABSTRACT OF THE DISSERTATION Development of Co-Ni-Ga Ferromagnetic Shape Memory Alloys (FSMAs) by Investigating the Effects of Solidification Processing Parameters by Haamun Kalaantari Doctor of Philosophy, Graduate Program in Mechanical Engineering University of California, Riverside, March 2013 Professor Reza Abbaschian, Chairperson Among Ferromagnetic Shape Memory Alloys (FSMAs), Co-Ni-Ga ternary alloys have attracted great attention due to their high Curie and martensitic transformation temperatures as well as improved ductility. Single β phase undergoes the martensitic transformation in this system, which is the base of ferromagnetic shape memory effect. In this investigation, Electromagnetic Levitation (EML) technique was employed to assess the effect of bulk supercooling and rapid solidification on near Heusler-type dual phase Co Ni Ga and single phase Co Ni Ga (at%) compositions. The effects of γ+β 46 27 27 48 22 30 microstructure on the martensitic and austenitic transformation temperatures and magnetic properties were also investigated. The presence of γ phase was found to suppress the martensitic and austenitic transformations to below room temperature. Bulk supercooling and rapid solidification led to the formation of homogeneous single viii martensitic phase from hyperperitectic alloy, which under normal solidification form the dual γ+β phases. Moreover, in contrast with martensite forming from Co Ni Ga , the 48 22 30 hyperperitectic martensite in supercooled Co Ni Ga samples showed no grain 46 27 27 boundary microsegregation. The martensite also showed a high Curie temperature about 127°C and good directional magnetic properties, including different in- and out-of-plane magnetization up to saturation level, and different coercivity from around 14 Oe for in- plane direction to about 42 Oe at the 50° angle. The role of solidification variables and chemical composition in the microstructure, and phase transformation in the ternary alloys Co Ni Ga (at%) with x ranging up to 50, and Co Ni Ga (at%) with y 50 50-x x 100-2y y y ranging from 15 to 35 were studied as well. For the metastable single β phase of supercooled Co Ni Ga alloy in Co Ni Ga series, the martensitic transformation 50 22.5 27.5 50 50-x x showed thermal stability during cyclic cooling and heating (up to 350°C) revealing its potential as a FSMA candidate. In Co Ni Ga series, on the other hand, paramagnetic 100-2y y y Co Ni Ga alloy showed martensite to austenite transformation temperature higher than 40 30 30 470°C, indicating its potential as High Temperature Shape Memory Alloy (HTSMA). ix