UUnniivveerrssiittyy ooff TTeennnneesssseeee,, KKnnooxxvviillllee TTRRAACCEE:: TTeennnneesssseeee RReesseeaarrcchh aanndd CCrreeaattiivvee EExxcchhaannggee Doctoral Dissertations Graduate School 12-2016 DDeevveellooppmmeenntt ooff aann ff--eelleemmeenntt sseeppaarraattiioonn cchheemmiissttrryy uussiinngg ssoolliidd eelleeccttrroollyytteess Kristian Guy Myhre University of Tennessee, Knoxville, [email protected] Follow this and additional works at: https://trace.tennessee.edu/utk_graddiss Part of the Analytical Chemistry Commons, Inorganic Chemistry Commons, Materials Chemistry Commons, and the Radiochemistry Commons RReeccoommmmeennddeedd CCiittaattiioonn Myhre, Kristian Guy, "Development of an f-element separation chemistry using solid electrolytes. " PhD diss., University of Tennessee, 2016. https://trace.tennessee.edu/utk_graddiss/4155 This Dissertation is brought to you for free and open access by the Graduate School at TRACE: Tennessee Research and Creative Exchange. It has been accepted for inclusion in Doctoral Dissertations by an authorized administrator of TRACE: Tennessee Research and Creative Exchange. For more information, please contact [email protected]. To the Graduate Council: I am submitting herewith a dissertation written by Kristian Guy Myhre entitled "Development of an f-element separation chemistry using solid electrolytes." I have examined the final electronic copy of this dissertation for form and content and recommend that it be accepted in partial fulfillment of the requirements for the degree of Doctor of Philosophy, with a major in Energy Science and Engineering. Thomas A. Zawodzinski, Major Professor We have read this dissertation and recommend its acceptance: Miting Du, Rose A. Boll, Claudia J. Rawn, Adam J. Rondinone, David W. DePaoli Accepted for the Council: Carolyn R. Hodges Vice Provost and Dean of the Graduate School (Original signatures are on file with official student records.) Development of an f‒element separation chemistry using solid electrolytes A Dissertation Presented for the Doctor of Philosophy Degree The University of Tennessee, Knoxville Kristian Guy Myhre December 2016 ii Copyright © 2016 by Kristian Guy Myhre All rights reserved. iii Dedication To my beautiful and precious wife, whom I adore endlessly: I have never loved you so much and I will never love you so little again, Bethany. iv Acknowledgements It is a nearly impossible task to decide where to start in thanking those who have helped me get to this point. Certainly, it is truly impossible to decide where to end, as there have been too many people that have helped me along the way to count. First and foremost, I want to thank my wife and family. Bethany, you are the most amazing wife and more than I deserve. I have been and continue to be extremely blessed by your supportive and endless love. I am beyond excited to continue sharing every day of my life with you. Mom, thank you for enabling and encouraging me to pursue an education that I enjoyed. Dad, thank you for showing me that family comes first and that hard work coupled with integrity is its own reward. Kameron and Kjasa, thank you for keeping me humble in the way only siblings can. I want to also thank my in‒laws, who have been an immensely important part of my life in Tennessee. I want to sincerely thank those at the University of Tennessee and Oak Ridge National Laboratory for giving me so many wonderful opportunities during my time in graduate school. I am especially thankful to Dr. Lee Riedinger for accepting me into the Bredesen Center for my graduate studies as well as personally ensuring my time as a graduate student was successful. The Radiochemical Engineering Development Center has been an extremely exciting place to carry out my dissertation research. The opportunities and support I have been provided as a member of the Nuclear Materials Processing group have been unbelievable. I am also extremely thankful to all of my graduate committee members, each of which has been instrumental in my graduate education. I look forward to continuing to work with all of them. I want to also thank those that encouraged me throughout the pursuit of my undergraduate degree and helped grow my passion for chemistry, particularly in the areas of separation chemistry, radiochemistry, and electrochemistry. v Abstract The f‒elements (lanthanides and actinides) have numerous applications and are critically important to many industries, including the energy, security, and medical industries. One of the barriers to increased use and availability of the f‒elements is the difficulty in separating them from each other due to their similar chemistries. This is especially true of the trivalent f‒elements (lanthanides and minor actinides). The development of separation techniques that maximize the differences in the physicochemical properties of the f‒elements is therefore an important area of research. For these reasons, an effort was undertaken to explore the use of solid electrolyte materials to accomplish separations of the f‒elements. The results of this work have led to the development of a novel separation method at Oak Ridge National Laboratory for accomplishing f‒element separations using inorganic solid electrolyte materials, specifically beta´´‒alumina. The use of beta´´‒alumina was both investigated both as an ion exchanger and selective membrane. Given the large dependence of superionic conductivity upon the valence of mobile ions, oxidation state control of the ions to be separated was explored. The high‒temperature regimes (greater than 300°C) required for superionic conduction of multivalent metal ions in beta´´‒alumina necessitated the use of molten salts as a medium to contain ions to interact with the solid electrolyte. These studies also included the development of Laser Induced Breakdown Spectroscopy for determining the concentrations of f‒elements in the alumina based materials. vi Preface “Captain, you almost make me believe in luck.” – Spock vii Table of Contents Chapter 1 Introduction and motivation .............................................................................. 1 1.1 Use of f‒elements in society ..................................................................................... 2 1.2 Project motivation ..................................................................................................... 3 1.3 Scope of work ........................................................................................................... 4 1.4 References ................................................................................................................. 8 Chapter 2 Background ..................................................................................................... 11 2.1 Separation of the f‒elements ................................................................................... 12 2.2 Separations using solid electrolytes ........................................................................ 17 2.3 References ............................................................................................................... 22 Chapter 3 Quantification of rare earths in alumina matrix via laser induced breakdown spectroscopy ...................................................................................................................... 27 3.1 Disclosure ............................................................................................................... 28 3.2 Abstract ................................................................................................................... 28 3.3 Introduction ............................................................................................................. 29 3.4 Materials and characterization ................................................................................ 32 3.5 Results and discussion ............................................................................................ 36 3.6 Conclusion .............................................................................................................. 40 3.7 Acknowledgements ................................................................................................. 41 3.8 References ............................................................................................................... 43 Chapter 4 Oxidation state behavior of rare earths in beta´´‒alumina by x‒ray photoelectron spectroscopy ............................................................................................... 45 4.1 Disclosure ............................................................................................................... 46 4.2 Abstract ................................................................................................................... 46 4.3 Introduction ............................................................................................................. 47 4.4 Materials and characterization ................................................................................ 48 4.5 Results and discussion ............................................................................................ 50 4.6 Conclusion .............................................................................................................. 53 4.7 Acknowledgements ................................................................................................. 54 4.8 References ............................................................................................................... 55 viii Chapter 5 Separation of f‒elements by ion exchange reactions between molten salts and beta´´‒alumina .................................................................................................................. 57 5.1 Disclosure ............................................................................................................... 58 5.2 Abstract ................................................................................................................... 58 5.3 Introduction ............................................................................................................. 59 5.4 Materials and characterization ................................................................................ 60 5.5 Results and discussion ............................................................................................ 63 5.6 Conclusion .............................................................................................................. 71 5.7 Acknowledgements ................................................................................................. 72 5.8 References ............................................................................................................... 73 Chapter 6 Reduction of Eu in molten CsCl‒MgCl and subsequent separation from Sm 2 using a beta´´‒alumina membrane .................................................................................... 76 6.1 Disclosure ............................................................................................................... 77 6.2 Abstract ................................................................................................................... 77 6.3 Introduction ............................................................................................................. 77 6.4 Materials and characterization ................................................................................ 79 6.5 Results and discussion ............................................................................................ 81 6.6 Conclusion .............................................................................................................. 82 6.7 Acknowledgements ................................................................................................. 82 6.8 References ............................................................................................................... 84 Chapter 7 Conclusions and recommendations ................................................................. 86 7.1 Important conclusions ............................................................................................. 87 7.2 Recommendations for future work ......................................................................... 87 7.3 References ............................................................................................................... 90 Appendix ........................................................................................................................... 91 Vita .................................................................................................................................. 131