Professor Maric’s research interests include the effect of structure, defects, and microstructure on transport and electrical properties of surfaces and interfaces. In particular, she is interested in developing novel materials for fuel cells, batteries and biosensors, durability study, any of the shortcomings of traditional vapor deposition techniques while yielding equal or better quality coatings at a lower cost. RSDT not only provides high quality active films/coatings (e.g., catalysts/electrodes/ thermal barriers coating), it also reduces the manpower, energy consumption and a number of processing steps required to assemble these films. More specifically, RSDT combines materials synthesis and deposition into a single step with several control features, replacing at least five unit operations in a conventional electrode manufacturing scheme. performance and life prognosis, aging, material state changes, and long term behavior. She developed the Reactive Spray Deposition Technology (RSDT), a thin-film deposition process that overcomes m.
Areas of Expertise (7)
Sustainable Energy Technologies
University of Kyoto: Ph.D.
Media Appearances (7)
How Green Are Electric Vehicles?
New York Times print
Experts point out that spent batteries contain valuable metals and other materials that can be recovered and reused. Depending on the process used, battery recycling can also use large amounts of water, or emit air pollutants. “The percentage of lithium batteries being recycled is very low, but with time and innovation, that’s going to increase,” said Radenka Maric, a professor at the University of Connecticut’s Department of Chemical and Biomolecular Engineering.
The Big Question with Radenka Maric: On the Role of Scientists in Society
Scientific Inquirer online
Dr. Radenka Maric is the Vice President for Research, Innovation and Entrepreneurship and CT Clean Energy Fund Professor of Sustainable Energy in the Department of Chemical & Biomolecular Engineering and the Department of Material Science & Engineering at the University of Connecticut and UConn Health, with responsibility for research leadership and technology commercialization of one of the top twenty-five public research universities in the United States, including its academic medical center. Dr. Maric graciously agreed to share her thoughts regarding SCINQ’s Big Question.
Maric leads UConn’s research, innovation and entrepreneurship
Hartford Business Journal online
As an engineer, Radenka Maric has seen her work incorporated into cutting-edge car engines that tap into hydrogen fuel cells for power. As a senior executive at the University of Connecticut, Maric has seen her work both in the institution’s burgeoning research portfolio and the proud faces of graduating undergraduate and graduate students.
New Drug Delivery System Targets Diseases at a Genetic Level
Technology Networks online
"There is no question that joining forces with industry partners to leverage our unique resources and expertise helps transform discoveries from an invention to an innovation that benefits society," says Radenka Maric, UConn's vice president for research. "We're committed to continuing to foster an entrepreneurial and industry-aware culture at the University to ensure UConn research has a positive impact on the health of Connecticut's citizens, as well as our economy."
Researcher, Painter, Pianist, Seamstress: The Many Shades of Radenka Maric
Hartford Courant print
To begin to describe Radenka Maric would already be to fail; if there is a single thread that runs through her life, it would be her belief that humans cannot be reduced to anything so singular. Maric is an administrator, engineer, painter, pianist, clothier and amateur chef. She was born in the former Yugoslavia, educated in Japan and is now based in Storrs, where she arrived in 2010 as a professor of chemical and biomolecular engineering. Last summer Maric, 51, was appointed as UConn’s vice president for academic research, charged with UConn's $260 million in research enterprise funds.
In budget talks, professors’ workloads become an issue
Tom Ebaugh, working toward a Ph.D. in chemical engineering, says Radenka Maric is the reason he’s doing it at the University of Connecticut. “I wouldn’t be here if she wasn’t,” said Ebaugh, 24, wearing plastic gloves and protective glasses at a fuel cell energy laboratory, part of UConn’s Center for Clean Energy Engineering. Originally from Pennsylvania, he is among a handful of graduate students working under Maric, who is not only a professor in sustainable energy, but as of July, vice president of academic research at Connecticut’s flagship university.
New Florescent Dyes Could Help Doctors Image and Diagnose Diseases
The research team’s next steps will take this innovative design and run with it — hopefully making the method and VSD commercially available. As stated by Radenka Maric, UConn’s vice president for research, “Dr. Loew’s experience is a prime example of how the NSF I-Corp program can transform high-potential academic discoveries into viable products and services … Accelerate UConn helps our preeminent faculty move their ideas beyond the lab so they can join the ranks of other successful entrepreneurs and industry leaders, and have an impact in our communities and on the economy.”
Pathways to ultra-low platinum group metal catalyst loading in proton exchange membrane electrolyzersCatalysis Today
Radenka Maric, et al.
2016 Hydrogen is one of the world's most important chemicals, with global production of about 50 billion kg/year. Currently, hydrogen is mainly produced from fossil fuels such as natural gas and coal, producing CO2. Water electrolysis is a promising technology for fossil-free, CO2-free hydrogen production...
A Study on Reactive Spray Deposition Technology Processing Parameters in the Context of Pt Nanoparticle FormationJournal of Thermal Spray Technology
Justin M. Roller and Radenka Maric
2015 Catalytic materials are complex systems in which achieving the desired properties (i.e., activity, selectivity and stability) depends on exploiting the many degrees of freedom in surface and bulk composition, geometry, and defects. Flame aerosol synthesis is a process for producing nanoparticles with ample processing parameter space to tune the desired properties. Flame dynamics inside the reactor are determined by the input process variables such as solubility of precursor in the fuel; solvent boiling point; reactant flow rate and concentration; flow rates of air, fuel and the carrier gas; and the burner geometry...