Johannes W. Schwank
Professor
Chemical Engineering
University of Michigan
United States of America
Biography
Society Memberships AICHE ACS North American Catalysis Society Positions Held at U-M James and Judith Street Professor of Chemical Engineering (2009-present) Director, Researching Fresh Solutions to the Energy/Water/Food Challenge in Resource-Constrained Environments (REFRESCH) (2013 – present) Director, Electron Microbeam Analysis Laboratory, (2013-2015) Interim Director, Energy Institute (2011-2012) Professor, Department of Chemical Engineering (1990-present) Associate Director, Electron Microbeam Analysis Laboratory (1986-2000) Associate Professor, Department of Chemical Engineering (1984-1990) Assistant Professor, Department of Chemical Engineering (1980-1984) Engineering Research Assistant, Department of Chemical Engineering (1979-1980) Postdoctoral Scholar, Department of Chemical Engineering (1978-1979) Positions Held Elsewhere Visiting Professor, University of Innsbruck, Austria, (1987-1988) Visiting Professor, Technical University, Vienna Austria, (1987) Guest Professor, Tianjin University, Tianjin, China (2011-2013) Courses Taught ChE 230 – Thermodynamics I ChE 342 – Heat and Mass Transfer ChE 344 – Reaction Engineering and Design ChE 460 – Chemical Engineering Laboratory II ChE 470 – Colloids and Interfaces ChE 486 – Chemical Process Simulation and Design I ChE 487 – Chemical Process Simulation and Design ChE 496 – Selected Topics: Hydrogen Technology I ChE 542 – Intermediate Transport Phenomena ChE 628 – Industrial Catalysis ChE 696 – Selected Topics: Chemical Sensors ChE 696 – Selected Topics: Fuel Cells and Fuel Processors ChE 696 – Selected Topics: Hydrogen Technology ChE 696 – Selected Topics: Fossil and Renewable Fuels ChE 697 – Problems in Chemical Engineering: Thin Films and Catalysis
Research Interest
Our research program is focused on fundamental and applied research problems in heterogeneous catalysis, sensors, and energy storage materials. A major theme is the development of correlations between surface structure of materials and their reactivity. The laboratories are equipped with comprehensive catalyst and materials characterization facilities. In the area of heterogeneous catalysis, we focus on correlations between the catalyst structure and composition and catalytic function in reactions of industrial importance. Principles of nucleation, clustering, and growth of small particles on support materials are under investigation, with emphasis on bimetallic catalyst systems and oxide catalysts. Of particular interest are geometric and electronic interactions between catalyst components as a means to modify catalytic activity and selectivity. A major thrust of our research efforts is the characterization of supported catalysts by analytical and high-resolution electron microscopy. The microstructural characterization results are then brought into context with X-ray diffraction, atomic absorption, neutron activation analysis, gas chemisorption and X-ray photoelectron spectroscopy data. In-situ spectroscopic techniques such as Fourier-Transform infrared spectroscopy are utilized to monitor adsorbed surface species under reaction conditions. These characterization data are then used to interpret kinetic results for hydrogen or oxygen transfer reactions obtained in flow reactors. Current catalysis projects include autothermal reforming of hydrocarbons, direct reforming solid oxide fuel cell catalysts, automotive emission control catalysis, Fischer-Tropsch catalysis, partial oxidation of hydrocarbons, photocatalytic oxidation and water splitting, and biomass conversion. In the area of sensors, our group has developed microelectronic gas sensors for a wide range of important applications, from monitoring the purity of microelectronic processing gases to environmental sensing and automotive exhaust gas sensing and diesel particulate sensing. Chemical species are detected on the basis of several principles, including gas adsorption-induced resistance and work function changes. In the energy storage area, we work on synthesis and characterization of battery electrode materials, with special focus on prototyping of multivalent intercalation cathode materials.
Publications
-
“Effect of Diluent Gas on Ethylene Epoxidation Activity over Various Ag-Based Catalysts on Selective Oxidation Supportsâ€, Atiporn Chongterdtoonskul, Thitiporn Suttikul, Malee Santikunaporn, Johannes W. Schwank, Sumaeth Chavadej, Journal Of Molecular Catalysis A: Chemical 386 (2014) 5-13.
-
“Nature of the two-step temperature-programmed decomposition of PdO supported on aluminaâ€, X. Chen, J. W. Schwank, G.B. Fisher, Y. Cheng, M. Yagner, R. W. McCabe, M. B. Katz, G.W. Graham, and X. Pan, Applied Catalysis A: General, 475 (2014) 420-426.
-
“Evaluation of Ni/SDC as anode material for dry CH4 fueled Solid Oxide Fuel Cellsâ€, Zhiming Wang, Yongdan Li, and Johannes W. Schwank, Journal of Power Sources 248 (2014) 239-245.
-
Crystalline structure refinements and properties of Ni/TiO2 and Ni/TiO2-Ce catalysts and application to catalytic reaction of “CO+ NOâ€,, Adolfo Romero-Galarza, Kevin A. Dahlberg, Xiaoyin Chen, Johannes W. Schwank, Applied Catalysis A: General478 (2014) 21-29.
-
“In situ tracing of atom migration in Pt/NiPt hollow spheres during catalysis of CO oxidationâ€, Jialong Liu, Wei Liu, Qian Sun,Shouguo Wang, Kai Sun, Johannes Schwank and Rongming Wang, Chemical Communications 50 (2014) 1804-1807 ,