Peter C. Burns
PETER C. BURNS
301 Stinson Remick Hall
Notre Dame, Indiana 46556
Peter C. Burns, The Henry J. Massman Professor of Civil and Environmental Engineering and Earth Sciences, and concurrent professor in the Department of Chemistry and Biochemistry, was named director of ND Energy in July 2014. An accomplished researcher and administrator, Dr. Burns has served since 2009 as director of the Department of Energy funded, and recently renewed, Energy Frontier Research Center (EFRC) Materials Science of Actinides, and most recently received one of two Stewardship Science Academic Alliances Centers of Excellence grants from the Department of Energy's National Nuclear Security Administration. The Actinide Center of Excellence focuses on research in nuclear chemistry and radiative materials through the integration of physical experiments and computer simulation, enabling advanced experimental activities for students to be trained in key areas of stewardship science. Dr. Burns has focused most of his research over the past decade on the solid-state chemistry, mineralogy, and environmental chemistry of uranium, as well as the transuranic elements neptunium and plutonium.
The Burns research group published the first of a family of novel uranyl peroxide hydroxide spherical nanoclusters in 2005. To date, they have reported the synthesis and structures of nanoclusters containing 24, 28, 32, 40 and 50 uranium atoms. Additional papers will be forthcoming that report U16, U20 (multiple topologies), U24 (open), U36, U44 and U60. We will also be completing a "roadmap" for the synthesis of specific members of this complex family of actinide nano-scale clusters.
The Burns group has published extensively in uranium mineralogy, and has reported the crystal structures of dozens of uranyl minerals including autunite, bijvoetite, vandendriesscheite, wolsendorfite, boltwoodite, compreignacite, masuyite, haweeite, weeksite, fontanite, billietite, richetite, zippeite, and studtite.
The structure of studtite, reported by Burns and Kubatko (2003) is the first structure of a peroxide mineral, and the only one published to date. As reported by Kubatko et al. (2003) in Science, studtite forms in nature where radioactivity causes the formation of peroxide in water. Studtite was the first structure found that involved shared edges between any uranyl peroxide polyhedra, and the Burns group later developed a complex group of nano-structured uranium materials based upon this linkage.
The Burns group has examined the impacts of uranium mineralogy on the release of radionuclides from nuclear waste in a geological repository, such as Yucca Mountain. Much of the emphasis has been on neptunium, as it has a long half-life and is potentially mobile in the environment.
Burns has published extensively on borate mineralogy, copper minerals, and a variety of exotic new minerals. He has published structural hierarchies for borate minerals, sulfate minerals, inorganic uranium compounds, and inorganic neptunium compounds.