REU Student Innovators Wow Business Community
UConn Engineering hosted five National Science Foundation-funded Research Experiences for Undergraduates (REU) sites during the summer that enabled 43 undergraduates from across the nation to explore exciting research in engineering faculty laboratories. Among the REU programs was one that immerses students in both the research and entrepreneurial environments, Promoting Innovation and Entrepreneurship through Academic-Industrial Partnerships.
The students participating in that REU had the opportunity to present their work during the July 26 Innovation Connection academic/industry networking event hosted at Nerac in Tolland and co-sponsored by Nerac and OpenSky. Nerac president Kevin Bouley, who hosts a number of UConn start-ups in his Tolland facility, noted “This event showcases the collaborations between students, faculty and the private sector. It was very interesting to see RPM Sustainable Technologies participate, given that they are located in the Nerac building as a launching pad for their commercial enterprise.”
Before an audience of entrepreneurs, small business gurus, state government officials, IP experts, faculty and members of the investment community, each young researcher/entrepreneur delivered a two-minute “elevator pitch” presentation of his/her work and then spoke in greater detail with attendees during the informal networking event. The forum enabled the students to test their mettle in the real-world situation faced by entrepreneurs every day.
While all REU programs entail scholarly research, this innovation-oriented REU requires the students to participate in a business and entrepreneurship seminar taught by professor Richard Dino of the School of Business. Furthermore, the students’ research was co-sponsored by commercial businesses – a novel twist that underscores the commercial intent of the research challenges they addressed while working in the UConn faculty laboratories.
The REU theme was conceptualized by Dr. Jeffrey McCutcheon, assistant professor of Chemical & Biomolecular Engineering, and Entrepreneur-in-Residence Robin Bienemann, and NSF began funding the project in 2012. In his introductory remarks to the audience, Dr. McCutcheon explained the genesis of the Innovation REU and noted that his goal was to “introduce the students to applied science and the way products make it to market.”
Explore the other UConn Engineering REUs:
The nine innovation REU students and their projects are summarized below.
Joseph Amato (Univ. of Minnesota – Twin Cities) researched reactive spray deposition technology for the one-step production of catalysts and electrodes in fuel cells. His research aim was to improve the efficiency of proton exchange membrane (PEM) fuel cells for the fuel cell and fuel-cell automotive markets. Sponsor: Proton OnSite; faculty mentor: Dr. Radenka Maric (Materials Science & Engineering). Poster.
Isaac Batty (California State Univ. – Long Beach) researched bio-oil production from the fast catalytic pyrolysis of lignocellulosic biomass (trees). His objective was to investigate the effect of temperature and various catalyst/biomass ratios on the quality of bio-oil produced from biomass. Sponsor: W.R. Grace & Co.; faculty mentor: Dr. George Bollas (Chemical & Biomolecular Engineering). Poster.
Ryan Carpenter (Univ. of Buffalo)designed an experimental apparatus enabling researchers to observe the antimicrobial susceptibility of multispecies biofilms. Biofilms are common (e.g., dental plaques) and often contain multiple species of bacteria such as Staphylococcus aureus. Biofilms are a costly problem for many industries, including food processing, oil recovery and medical implant operations. Sponsor: BASF; faculty mentor: Dr. Leslie Shor (Chemical & Biomolecular Engineering). Poster.
William Hale (UConn) sought to understand whether acetate and butyrate influence the anaerobic fermentation of waste glycerol – a byproduct from biodiesel production – into 1,3-propanediol. 1,3-propanediol is used in the manufacture of polyesters, solvents, lubricants and other products. Sponsor: RPM Sustainable Technologies; faculty advisor: Dr. Richard Parnas (Chemical & Biomolecular Engineering). Poster.
Justine Jesse (Univ. of Massachusetts) researched heat treatments that produce the strongest possible electrospun nanofibers, used in water filtration and industrial plants, without compromising performance. Sponsor: KX Technologies; faculty mentor: Dr. Jeffrey McCutcheon (Chemical & Biomolecular Engineering). Poster.
Kyle Karinshak (Univ. of Oklahoma) researched the photocatalytic degradation of a specific fluorescent dye in aqueous environments through the use of a titanium oxide/metal doped catalyst. Kyle found titanium oxide/metal-doped fly ash to be an effective catalyst enabling the degradation of the dye, which is released from textile plants and inhibits the passage of sunlight through water/ Sponsor: VeruTEK Corp.; faculty mentor: Dr. Steven Suib (Chemistry; Institute for Materials Science). Poster.
Zachariah Rueger (Iowa State Univ.) sought to maximize the specific surface area of activated carbon nanofiber nonwoven mats, which are used in water purification and for electricity generation in certain fuel cells. A greater surface area allows greater volumes of wastewater to be purified quickly. Sponsor: KX Technologies; faculty mentor: Dr. Jeffrey McCutcheon (Chemical & Biomolecular Engineering). Poster.
Kyle Stachowiak (Vanderbilt Univ.) researched techniques to optimize the atomic layer deposition of copper on a component, the rectenna, used to enhance the performance of solar cells. A rectenna collects solar radiation and converts it to usable energy. Techniques for applying copper more reliably will improve the efficiency of solar cells. Sponsor: Scitech Associates LLC; faculty mentor: Dr. Brian Willis (Chemical & Biomolecular Engineering). Poster.
Urian Vue (UConn and Temple Univ.) explored the use of doped zinc stannate nanostructure film for use in optoelectronic devices. Optoelectronic devices are used in ultraviolet LEDs and sensors, combustion engine control and various secure and defense-related applications. Zinc stannate films are sensitive to the deep UP spectrum range and can be tuned to detect specific ranges. Sponsor: United Technologies Research Center; faculty mentor: Dr. Pu-Xian Gao (Materials Science & Engineering and IMS). Poster.