Highlights

Artist's renditions of processes the Johnson Lab uses to create thin film metal oxides and their precursors. These thin films may be used as environmentally safer alternatives to materials currently used in electronics. Left: Developing aqueous fluorine tin oxide clusters -- a precursor for thin films. Right: Depositing an aluminum indium solution precursor to make a thin film of aluminum indium oxide.

Artist’s renditions of processes the Johnson Lab uses to create thin film metal oxides and their precursors. These thin films may be used as environmentally safer alternatives to materials currently used in electronics. Left: Developing aqueous fluorine tin oxide clusters — a precursor for thin films. Right: Depositing an aluminum indium solution precursor to make a thin film of aluminum indium oxide.

With their research, Darren Johnson and his lab seek to create solutions that prevent toxic waste and detect and remove contaminants from the environment. One of the biggest successes that emerged from the Johnson Lab began as a failure during a collaboration with the Haley lab. An experiment intended to create chloride sensors produced a sensor that was selective for nitrate instead of chloride. An effective nitrate sensor, however, has the potential to be highly useful in agriculture. “Over one percent of the world’s energy goes to making ammonium nitrate fertilizer,” Johnson says, “and 30% of that’s wasted and ends up as an environmental pollutant, but it’s also lost revenue for the farmers — in the U.S. that’s 2.5 billion dollars of wasted fertilizer.” Johnson, Michael Haley and their former graduate student Calden Carroll “pitched [the sensor] to a federal agency to form a start up company, and have now raised 1.3 million in funding.” Carroll now heads the company, which incorporated in 2012, employs three other UO alumni, and receives support from the National Science Foundation’s Small Business Innovation Research Program, the Oregon Nanoscience and Microtechnologies Institute and the Oregon Built Environment & Sustainable Technologies Center.
To foster business success stories like that of Carroll for other university students, Johnson and the CSMC partnered with ecosVC to implement their Lens of the Market Innovation Program. The Lens of the Market Program helps students make the transition from classrooms and university laboratories to professional life by helping them develop entrepreneurial skills. “If you have a really fundamental understanding of market analysis,” Johnson says, “it can really help science research. Chemists are problem solvers, we want to know important problems, and understanding the market can really help you pick good problems.”
For Johnson, the Lens of the Market Program is one of many features that make the University of Oregon’s Materials Science Institute stand out among its peers. In addition, he names the “student-focused” nature of the program, with an emphasis on “cross-disciplinary” training. “We compete [with other universities’ science programs] by being collaborative,” Johnson says, with “smaller groups and more collaborations between the groups. We compete with facilities, because our facilities are phenomenal for a department our size, and we don’t share them with a big engineering school, or a big medical school, and that’s a huge advantage we have. […] This is a really exciting time to be a Duck, in the sciences, moving forward.”

 

 

  Chemist David Johnson’s research revolves around the creation of new compounds with new properties, using a breakthrough “slice and dice” method that he developed. This method involves slicing molecular structures into slabs, and layering the slabs together. “We try to understand how [chemical compounds’] properties correlate with their structure,” Johnson says, “so we can make new materials that have enhanced properties.” Johnson is also known for his discovery of materials with the lowest thermal conductivity ever observed.
When asked about his work, however, Johnson says the “key thing is the students.” Through the Materials Science Institute, Johnson created the Industrial Internship Graduate degree program, which trains 70-80 students annually for corporate internships. In 2014, the program saw 100% of participants obtain internships that pay an average salary of $50,000 per year. Historically, more than 98% of the participants get internships and nine out of ten participants get job offers with the companies that they intern with.
In his laboratory, Johnson attempts to tailor each student’s tasks to prepare them for their chosen career path. He emphasizes independent problem-solving skills, in line with his belief that the area for growth in his field is applied science —
Left: A visual analogy for the changes in energy states of materials as their molecules are rearranged. Right: The slice-and-dice process of designing inorganic isomers with new properties is inspired by molecular chemistry synthesis approaches.

Left: A visual analogy for the changes in energy states of materials as their molecules are rearranged. Right: The slice-and-dice process of designing inorganic isomers with new properties is inspired by molecular chemistry synthesis approaches.

science performed to contribute to fundamental understanding, that also might lead to creating practical, real-world solutions. His advice for students is to pursue a focus that they enjoy, with the knowledge that some hard work may be required along the way.