Patricia Thiel
Patricia A. Thiel is an American chemist and materials scientist who is a Distinguished Professor of Chemistry at Iowa State University. She is known for her research on atomic-scale structures and processes on solid surfaces.
Early life and Education
Thiel grew up on a farm in southwest Minnesota, near her birthplace of Adrian, Minnesota. Her parents grew up in immigrant farm families and each had completed an eighth grade education. Thiel herself attended a private elementary school nearby her farm in Lismore, MN for grades 1-8 and public high school in Adrian, MN for grades 9-12. Support from the National Merit Scholarship Program enabled her to attend Macalester College in St. Paul, MN, where she was inspired by her freshman chemistry course and its instructor, Prof. Emil Smirkowski to major in chemistry. She completed a BA in chemistry with a minor in mathematics in 1975. After working for a year at Control Data Corporation as an analytic chemist, she enrolled in the Chemistry Department at the California Institute of Technology, with financial support from a National Science Foundation Predoctoral Fellowship. She completed a PhD in chemistry in 1981 under the supervision of W. Henry Weinberg.Career
Thiel's first appointment after graduation was as an Alexander von Humboldt Fellow at the Ludwig Maximilian University of Munich, where she worked in the research group of Gerhard Ertl, who later went on to receive the 2007 Nobel Prize in Chemistry. In 1982 she joined the technical staff of Sandia National Laboratories in Livermore, CA and, after a brief stint as a Visiting Professor in the Physics department of the University of California, Berkeley, joined the Chemistry department faculty of Iowa State University in 1983, with a simultaneous appointment as staff scientist with the US Department of Energy's Ames Laboratory She was subsequently promoted to the ranks of Associate Professor, Full Professor and Distinguished Professor. She received an additional appointment as Professor of Materials Science and Engineering in 2012. Throughout this time period she received outstanding teaching awards, and held several administrative posts, including Program Director for Materials Chemistry, Chief Research officer and Chair of the Iowa State Chemistry Department. Thiel is an associate editor of The Journal of Chemical Physics. She attended the Nobel Prize ceremony on December 10, 2011, where Dan Shechtman received the 2011 Nobel Prize in chemistry for the discovery of quasicrystals.Research
Thiel's research has elucidated atomic-scale structures and processes on solid surfaces, in areas relevant to microelectronics, tribology, heterogeneous catalysis, and nanoscience. She has published over 300 research papers, which have been cited about 12,000 times, effective 2019. She is especially known for work in the following three areas.Surfaces of quasicrystals
Thiel's research group pioneered studies of nucleation and growth of metal films on quasicrystal surfaces, demonstrating that local pseudomorphic growth, including starfish-shaped formations, can occur at very specific nucleation sites.Focusing on metallic, aluminum-rich quasicrystals, Thiel and her collaborators extensively explored how quasicrystal atomic-scale surface structures were related to their unusual surface properties, including low friction, low adhesion, and good oxidation resistance.
Interaction of water with metal surfaces
Thiel's Ph.D. research described evidence for hydrogen bonding between water molecules on a ruthenium surface. She continued her research on water as a faculty member at Iowa State University, and discovered that desorption kinetics of water can exhibit a measurable isotope effect. She is credited with being the first to propose that bilayers of water near solid surfaces could possess a structure similar to the basal plane of Ice Ih.She is the co-author, along with Theodore E. Madey, of a highly cited and comprehensive review article describing the interactions and properties of water near solid surfaces.
Nucleation, growth, and coarsening of metal nanostructures on surfaces
Thiel's group is credited with discovering that large two-dimensional metal clusters actually diffuse on metal substrates, and that this can be the dominant mechanism leading to coarsening of these clusters. She and James W. Evans are responsible for first describing an atomic-scale mechanism for metal film growth, which they dubbed ‘downward funneling’. Because of this mechanism, they predicted an unusual variation in film roughness with temperature from theory, and eventually confirmed it experimentally using STM. This is now accepted as an important mechanism that affects thin film morphology upon growth at low temperature.More recently, her group discovered a series of naturally-occurring metal-sulfur complexes with distinct stoichiometries, which may influence stability of larger metallic features by assisting surface metal transport and hence coarsening. She and her collaborators also discovered that metallic nanoparticles can be grown as encapsulated clusters near the surface of a layered material, graphite, if specific growth conditions are met. Applying a continuum elasticity model, they developed insight into the reasons for the low, flattened shapes of these embedded particles, and a prediction that the shape of encapsulated metal islands should be universal.
Awards and honors
- 1984 Alfred P. Sloan Foundation Fellowship
- 1985 Presidential Young Investigator Award of the National Science Foundation
- 1986 Camille Dreyfus Teacher-Scholar Award
- 2005 Doctor Honoris Causa from the Institute National Polytechnique de Lorraine
- 2008 Iota Sigma Pi Honorary Member
- 2010 Arthur W. Adamson Award for Distinguished Service in the Advancement of Surface Chemistry
- 2010 David Adler Lectureship Award in the Field of Materials Physics
- 2012 Fellow of the Materials Research Society
- 2014 Physical Review Journals - Outstanding Referee
- 2014 Medard W. Welch Award
- John D. Corbett Professor in Chemistry
- Elected to the American Academy of Arts and Sciences in 2019.
Personal life