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Curriculum Vitae CURRICULUM VITA FOR SU HA EDUCATION Ph.D. in Chemical Engineering, University of Illinois, Urbana, IL Graduation: October, 2005 Advisor: Richard Masel Thesis: Direct Formic Acid Fuel Cells For Alternative Portable Power Sources M.S. in Chemical Engineering, University of Illinois, Urbana, IL Graduation: October 2003 Advisor: Richard Masel Thesis: Direct Formic Acid Polymer Electrolyte Membrane Fuel Cell B.S. in Chemical Engineering, North Carolina State University, Raleigh, NC Graduated with University Honors, June 2000; University Scholars Program Undergraduate Research Advisor: Saad Khan Research Project: Rheology of Protein Gels Synthesized Through a Combined Enzymatic and Heat Treatment Method PROFESSIONAL EXPERIENCE Associate Professor 2011-Present School of Chemical Engineering and Bioengineering Washington State University, Pullman, WA Assistant Professor 2005-2011 School of Chemical Engineering and Bioengineering Washington State University, Pullman, WA Graduate Research Assistant 2000-2005 Department of Chemical Engineering University of Illinois, Urbana, IL Undergraduate Research Assistant 1998-2000 Department of Chemical Engineering North Carolina State University, Raleigh, NC HONORS AND AWARDS 1. Outstanding Teaching Award, Chemical Engineering Department, Washington State University (2008). 2. 3rd Place, Dr. Bernard S. Baker Award for Fuel Cell Research, Fuel Cell Seminar and Fuel Cell Energy, Inc. (2005). 3. Nominated for the Glenn Award, ACS National Meeting (2005). 4. The 205th Meeting of the Electrochemical Society Travel Award, Energy Technology Division of the Electrochemical Society (2004). 5. Vodafone-U.S. Foundation Graduate Fellowship, University of Illinois (2003). 6. Finalist, The College Invention Competition 2003, The National Inventors Hall of Fame (2003). 7. Winner and Best of the Best, The 9th Annual Undergraduate Research Symposium, North Carolina State University (2000). 8. National Science Foundation (NSF) Research Experience for Undergraduates (REU) Program, North Carolina State University (Summer of 2000). 9. National Science Foundation (NSF) Research Experience for Undergraduates (REU) Program, University of Delaware (Summer of 1999). TEACHING Introduction to Transport Processes (undergraduate course) Fall 2005-2011 • Gave 3 one-hour lectures per week (3 credits) • Covered fundamentals of the phenomena governing the transport of momentum, energy, and mass using both microscopic and macroscopic approaches. • Applied the transport fundamentals to biological systems through homework and quiz problems • Incorporated COMSOL Multiphysics Modeling Software into the class to enhance the students’ learning of transport phenomena: a COMSOL tutorial on transport phenomena was developed and posted on the class webpage, and it was incorporated into class homework problems and the class project. Kinetics and Reactor Design (undergraduate course) Spring 2006-2012 • Gave 3 one-hour lectures per week (3 credits) • Understanding the basic concepts of chemical kinetics and chemical reactor design. • Incorporated COMSOL Multiphysics Modeling Software into the class to enhance the students’ learning of how chemical kinetics are affected by energy, mass, and momentum transport processes. Chemical Engineering Labs (undergraduate course) Spring 2007 & Fall 2007 • Developed a hydrogen fuel cell experimental setup and module for undergraduate students to help them in experiencing and understanding hydrogen fuel cell technology and hydrogen economics. • With permission from course instructors (Dr. Lee for Spring 2007 & Dr. Thiessen for Fall 2007), instructed undergraduate students on basic electrochemistry and electrokinetics concepts that are relevant to fuel cell technology. Chemical Engineering Labs (undergraduate course) Fall 2009 • Taught 6 one-hour labs and gave one 1-hour lecture per week (3 credits) • Provided laboratory experiments to the students on heat and mass transfer, separation, kinetics and fluid dynamics as well as teaching them how to write technical reports and how to give technical presentations. Conversion of Biomass to Biofuels (graduate course) Spring 2010 • Organized a lecture series on both biological and thermo-chemical processes used for converting various biomasses to value added products. • Provided experimental demonstrations of producing biodiesel from vegetable oil and driving the Volkswagen Beetle with the biodiesel to the students. • Teaching them how to write technical reports and how to give technical presentations. Catalysis (graduate course) Spring 2011 • Give 3 one-hour lectures per week (3 credits) • Understanding the basic concepts of heterogeneous catalysis. • Introduced various characterization methods and tools for heterogeneous catalysis. • Introduced important heterogeneous catalysis examples that are relevant to alternative and renewable energy. PUBLICATIONS 1. Hu, S.; Fabian, M.; Noborikawa, J.; Haan, J.; Scudiero, L.; Ha, S. Carbon supported Pd-based bimetallic and trimetallic catalyst for formic acid electrochemical oxidation. Applied Catalysis B (2015), 180, pp. 758-765. 2. Shah, S.; Marin-Flores, O.; Norton, M.G.; Ha, S. Molybdenum carbide supported nickel–molybdenum alloys for synthesis gas production via partial oxidation of surrogate biodiesel. Journal of Power Sources (2015), 294, pp. 530-536. 3. Kwon, B.; Hu, S.; He, Q.; Marin-Flores, O.; Oh, C.H.; Yoon, S.P.; Kim, J.; Breit, J.; Scudiero, L.; Norton, M.G.; Ha, S. Nickel-based anode with microstructured molybdenum dioxide internal reformer for liquid hydrocarbon-fueled solid oxide fuel cells. Applied Catalysis B (2015), 179, pp. 439-444. 4. Cuba-Torres, C.; Marin-Flores, O.; Owen, C.; Wang, Z.; Garcia-Perez, M.; Norton, M.G.; Ha, S. Catalytic partial oxidation of biodiesel surrogate over molybdenum dioxide. Fuel (2015), 146, pp. 132-137. 5. He, Q., Marin-Flores, O.; Hu, S.; Scudiero, L.; Ha, S.; Norton, M.G. Kinetics of hydrogen reduction of titanium-doped molybdenum dioxide. Scripta Materialia (2015), 100, pp. 55-58. 6. Kim, J.H.; Jun, S.A.; Kwon, Y.; Ha, S.; Sang, B.; Kim, J.B. Enhanced electrochemical sensitivity of enzyme precipitate coating (EPC)-based glucose oxidase biosensors with increased free CNT loadings. Bioelectrochemistry (2015), 101, pp. 114-119. 7. Hou, X.; Marin-Flores, O.; Kwon, B.; Kim, J. Norton, M.G.; Ha, S. Gasoline-fueled solid oxide fuel cell with high power density. Journal of Power Sources (2014), 268, pp. 546-549. 8. He, Q., Marin-Flores, O.; Hu, S.; Scudiero, L.; Ha, S.; Norton, M.G. Effect of titanium doping on the structure and reducibility of nanoparticle molybdenum dioxide. Journal of Nanoparticle Research (2014), 16, pp. 2385-2397. 9. Kwon, B.; Hu, S.; Marin-Flores, O.; Norton, M.G.; Kim, J.; Scudiero, L.; Breit, J.; Ha, S. High Performance Molybdenum Dioxide-Based Anode for Dodecane-Fueled SOFCs with a Maximum Power Density of 2 W cm2 at 750 oC. Energy Technology (2014), 2 (5), pp. 425-430. 10. Che, F.; Zhang, R.; Hensley, S.; Ha, S.; McEwen, J.S. Decomposition of Methyl Species on a Ni(211) surface: Investigations of the Electric Field Influence. ACS Applied Materials and Interfaces (2014), 4, pp. 4020-4035. 11. Sadiki, A.; Vo, P.; Hu, S.; Copenhaver, T.; Scudiero, L.; Ha, S. Haan, J. Increased Electrochemical Oxidation Rate of Alcohols in Alkaline Media on Palladium Surfaces Electrochemically Modified by Antimony, Lead, and Tin. Electrochimica Acta (2014), 139, pp. 302-307. 12. Noborikawa, J.; Lau, J.; Ta, J.; Hu, S.; Scudiero, L.; Derekhshan, S.; Ha, S.; Haan, J. Palladium-Copper Electrocatalyst for Promotion of Oxidation of Formate, Ethanol, and 2 Propanol in Alkaline Media. Electrochimica Acta (2014), 137, pp. 654-660. 13. Bahrami, J.; Gavin, P.; Bliesner, R.; Ha, S.; Pedrow, P.; Mehrizi-Sani A.; Leachman, J. Effect of Orthohydrogen-Parahydrogen Composition on Performance of a Proton Exchange Membrane Fuel Cell. International Journal of Hydrogen Energy (2014), 39, pp. 14955-14958. 14. Kim, R.E.; Hong, S.G.; Ha, S.; Kim, J.B. Enzyme adsorption, precipitation and crosslinking of glucose oxidase and laccase on polyaniline nanofibers for highly stable enzymatic biofuel cells. Enzyme and Microbial Technology (2014), 66, pp. 35-41. 15. Kwon, B.; Ellefson, C.; Breit, J.; Kim, J.; Norton, M.; Ha, S. Molybdenum Dioxide- Based Anode for SOFC Applications. Journal of Power Sources (2013), 243, pp. 203- 210. 16. Hu, S.; Scudiero, L.; Ha, S. Electronic effect of Pd-transition metal bimetallic surfaces toward formic acid electrochemical oxidation. Electrochemistry Communications (2013), 38, pp. 107-109. 17. Hu, S.; Scudiero, L.; Ha, S. Temperature dependence study of Pd–Cu supported bimetallic films by photoelectron spectroscopy and cyclic voltammetry. Electrochimica Acta (2013), 105, pp. 362-370. 18. Wang, Z.; McDonald, A.G.; Westerhof, R.; Kersten, S.; Cuba-Torres, C.; Ha, S.; Pecha, B.; Garcia-Perez, M. Effect of Cellulose Crystallinity on the Formation of a Liquid Intermediate and on Product Distribution during Pyrolysis. Journal of Analytical and Applied Pyrolysis (2013), 100, pp. 56-66. 19. Ha, S.; Wee, Y.; Kim, J. Nanobiocatalysis for Enzymatic Biofuel Cells. Topics in Catalysis (2012), 55, pp. 1181-1200. 20. Shuozhen, H.; Scudiero, L.; Ha, S. Electronic Effect on Oxidation of Formic Acid on Supported Pd-Cu Bimetallic Surface. Electrochimica Acta (2012), 83(30), pp. 354-358. 21. Ellefson, C.A.; Marin Flores, O.; Ha, S.; Norton, M.G. Synthesis and applications of molybdenum (IV) oxide. Journal of Material Science (2012), 47(5), pp. 2057-2071. 22. Kwon, B.W.; Tan, M.; Ohlsen,
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