TSUFI PREM is a partnership between Tennessee State University (TSU), Fisk University, and the Illinois Materials Research Science and Engineering Center (TSU-Fisk-Illinois, or TSUFI), funded through the National Science Foundation Partnerships for Research and Education in Materials (PREM) program. The Illinois Materials Research Science and Engineering Center (I-MRSEC) is located at the University of Illinois at Urbana-Champaign (UIUC).TSUFI PREM creates strategic research opportunities and exchanges, structured within a supportive framework of education, career preparation, and cross-institutional mentoring, that will increase access to advanced materials facilities and training of underrepresented minority (URM) undergraduates. It will build recruitment pathways to increase the enrollment of URMs in materials-related graduate programs at TSU, Fisk, and UIUC, ultimately increasing the number of minority STEM graduates prepared for materials science careers in industry, government, and academia. NSF news release: See Article Here

Photo of Dr. Frances Williams and April Falconer working in the lab at Tennessee State University.
Dr. Frances Williams and April Falconer working in the lab at Tennessee State University.

Credit: Tennessee State University, Dr. Frances Williams



TSUFI PREM Leadership

Director:  Prof. Frances Williams,Tennessee State University
Co-Director: Prof. Richard Mu, Tennessee State University
Co-PI: Prof. Eugene Collins, Fisk University
Co-PI: Prof. Nadya Mason, UIUC
Co-PI: Prof. Virginia Lorenz, UIUC
Prof. Ranganathan Parthasarathy, Tennessee State University
Prof. Lei Qian, Fisk University
Prof. Abiodun Fasoro, Tennessee State University
Prof. Catherine Murphy, UIUC
Dr. Pamela Pena Martin, UIUC

TSUFI PREM Research Areas
Next-generation wearable electronics and biosensors have important applications in medicine, the environment, and biology. Realizing these technologies require materials that are simultaneously deformable, selectively sensitive to their environment, and electrically active. Piezoelectric polymeric thin films and nanofibers are excellent candidates for these applications because they are flexible, chemically inert, can be doped, and have a high surface-to-volume ratio suitable for specific sensing applications. The grand challenges the TSUFI PREM addresses comprise two thrusts:

Thrust I:  Low-dimensional (NFs and films) polymeric materials synthesis and characterization
Lead:  Prof. Richard Mu
Co-lead: Prof. Frances Williams

Photoconductivity data plot,  with micrographs of nanowires.
Photoconductivity measurement of ZnO nanowire doped and undoped with electrospun polyvinylidene fluoride nanofibers.

Establish design rules of materials synthesis to optimize the functionality of ferroelectric polymeric materials and develop scalable manufacturing through fundamental understanding of the basic science and physical materials processing

Thrust II: Production and modeling of heterostructures containing 2D materials
Lead: Prof Ranganathan Parthasarathy

Schematic of a surface acoustic wave sensing device based on parallel nanofibers
Schematic of a surface acoustic wave sensing device based on parallel nanofibers as an acoustic wave generation and detection platform.

Integrate the materials with other deformable materials through interface   engineering to achieve nanosystems and nanodevices whose properties and functionality are far beyond that of the single materials alone. 2D materials, for example, can serve as excellent deformable electrodes and be used for high-mobility electronics.