Paul Dauenhauer


Paul Dauenhauer, a chemical engineer, is the Lanny Schmidt Honorary Professor at the University of Minnesota. He is recognized for his research in catalysis science and engineering, especiall, his contributions to the understanding of the catalytic breakdown of cellulose to renewable chemicals, the invention of oleo-furan surfactants, and the development of catalytic resonance theory.

Early Life & Education

Paul Dauenhauer was born in 1980 in Texas, USA, and was raised in Wisconsin Rapids, WI, attending Lincoln High School. He received his bachelor's degree in chemical engineering and chemistry at the University of Wisconsin, Madison in 2004. Working under the supervision of Lanny Schmidt at the University of Minnesota, Dauenhauer received his Ph.D. in chemical engineering in 2008 from the Department of Chemical Engineering & Materials Science. His dissertation described the development of reactive flash volatilization and was titled "Millisecond autothermal catalytic reforming of carbohydrates for synthetic fuels by reactive flash volatilization".

Career

Following graduation from Minnesota, Dauenhauer served as a Senior Research Engineer at the Dow Chemical Company in Midland, MI, and Freeport, TX. He started as an Assistant Professor at the University of Massachusetts, Amherst in 2009 before promotion to Associate Professor in 2014. In 2014, he moved to the Department of Chemical Engineering & Materials Science at the University of Minnesota, where he was promoted to Professor, and then and Lanny Schmidt Honorary Professor in 2019. During this time, he co-founded or contributed to the founding of startup companies Activated Research Company, Sironix Renewables, and enVerde, LLC.

Renewable Chemicals

Dauenhauer's focus on renewable chemicals produced from glucose has targeted both drop-in replacement chemicals and new chemicals with novel characteristics. In 2012, he discovered a high yield pathway to synthesize p-xylene from glucose; this molecule is the key ingredient in polyethylene terephthalate plastic. This process technology utilized a new class of weak acid zeolites that permits the manufacture of biorenewable polyester.
In 2015, Dauenhauer and his team developed a new class of surfactants, detergents, and soaps that are derived from biomass. These molecules were shown to have high hard water stability and are being commercialized by Sironix Renewables, Inc.
In 2016, Dauenhauer and Abdelrahman developed the acid-catalyzed dehydra-decyclization mechanism that simultaneously opens cyclic ether rings and dehydrates to synthesize diene products. This technology was subsequently used to optimize the catalytic production of isoprene, the key chemical in the production of car tires. Subsequent research identified pathways to similarly convert biomass-derived tetrahydrofuran to butadiene and 2-methyl-tetrahydrofuran to piperylene.
Key publications include:
Dauenhauer's study of cellulose in 2008 led to the discovery of an intermediate liquid state of short-chain cellulose oligomers of sub-second duration at temperatures around 500 deg C. He further outlined the challenges in understanding high temperature cellulose chemistry by publishing his "Top Ten Challenges" of biomass pyrolysis in 2012, one of which was based on his discovery of the mechanism of aerosol formation through liquid intermediate cellulose.
Dauenhauer further developed a new reactor technique called 'PHASR' which led to the first isothermal kinetics of cellulose conversion and product formation. This technique permitted a molecular analysis of cellulose activation and the discovery that cellulose has a unique reaction transition at 467 deg C. The high temperature kinetic transition was attributed to the catalytic role of chain-to-chain cellulose hydroxyl groups in stabilizing the chain fragmentation of inter-monomer bonds.
Key publications include:
was proposed by Dauenhauer based on the Sabatier principle of catalysis developed by French chemist Paul Sabatier. Optimal catalyst performance is depicted as a 'volcano' peak using a descriptor of the chemical reaction defining different catalytic materials. Experimental evidence of the Sabatier principle was first demonstrated by Balandin in 1960. In his initial discovery of the behavior of oscillating chemical reactions on metal surfaces, Dauenhauer showed that steady state reaction rates could achieve chemical reaction speeds as much as 1000 times greater than previously achievable rates, even with optimized catalytic systems. This work broke down surface chemical reactions into its component parts and associated natural frequencies, which could be matched to resonate with the catalytic surface frequencies.
Follow-up work on catalytic resonance theory by Dauenhauer and his team broadened to understand the relationship between surface chemistry with its linear scaling relationships and the surface binding energy oscillation waveform. He introduced the concept of superVolcanoes as a superposition of all possible Sabatier volcanoes for varying linear scaling parameters, before further connecting the behavior of oscillating catalytic surfaces to molecular machines and pumps.
Key publications include:
Professor Dauenhauer has supervised 12 Ph.D. students and advised six post-doctoral scholars. He has published over 90 peer-reviewed papers and 10 patents. He has given over 50 invited seminars and lectures including the Notre Dame Thiele lecture in 2017 and the Purdue Mellichamp lecture in 2016. He has received numerous awards for his work including: