Erin L. Ratcliff is a Full Professor in the School of Materials Science and Engineering and the School of Chemistry and Biochemistry at Georgia Tech and holds a joint appointment at the National Renewable Energy Laboratory. After completing a postdoc at the University of Arizona, she served as a Research Scientist and Research Professor in the Department of Chemistry and Biochemistry. She was previously an Assistant and Associate Professor in the Department of Materials Science and Engineering and the Department of Chemical and Environmental Engineering at the University of Arizona.
Her group “Laboratory for Interface Science for Printable Electronic Materials” works on both fundamentals and devices for energy conversion and storage and sensing, including solar cells, transistors, photoelectrodes, transistors, capacitors, and batteries. The group is predominantly experimental and uses a combination of electrochemistry, spectroscopies, microscopies, and synchrotron-based techniques to understand structure-property relationships across time and length scales, with an emphasis on charge transport and charge transfer. Materials of interest include metal halide perovskites, π-conjugated materials, colloidal quantum dots, and metal oxides. Current research and funding includes semiconductor/electrolyte interfaces and durability of printable electronic materials from multiple federal agencies. Such an interdisciplinary group welcomes students and postdocs with training in materials science, chemical engineering, chemistry, and physics, among others.
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Degrees
Erin L. Ratcliff is a Full Professor in the School of Materials Science and Engineering and the School of Chemistry and Biochemistry at Georgia Tech and holds a joint appointment at the National Renewable Energy Laboratory. After completing a postdoc at the University of Arizona, she served as a Research Scientist and Research Professor in the Department of Chemistry and Biochemistry. She was previously an Assistant and Associate Professor in the Department of Materials Science and Engineering and the Department of Chemical and Environmental Engineering at the University of Arizona.
Her group “Laboratory for Interface Science for Printable Electronic Materials” works on both fundamentals and devices for energy conversion and storage and sensing, including solar cells, transistors, photoelectrodes, transistors, capacitors, and batteries. The group is predominantly experimental and uses a combination of electrochemistry, spectroscopies, microscopies, and synchrotron-based techniques to understand structure-property relationships across time and length scales, with an emphasis on charge transport and charge transfer. Materials of interest include metal halide perovskites, π-conjugated materials, colloidal quantum dots, and metal oxides. Current research and funding includes semiconductor/electrolyte interfaces and durability of printable electronic materials from multiple federal agencies. Such an interdisciplinary group welcomes students and postdocs with training in materials science, chemical engineering, chemistry, and physics, among others.
Degrees
Erin L. Ratcliff is a Full Professor in the School of Materials Science and Engineering and the School of Chemistry and Biochemistry at Georgia Tech and holds a joint appointment at the National Renewable Energy Laboratory. After completing a postdoc at the University of Arizona, she served as a Research Scientist and Research Professor in the Department of Chemistry and Biochemistry. She was previously an Assistant and Associate Professor in the Department of Materials Science and Engineering and the Department of Chemical and Environmental Engineering at the University of Arizona.
Her group “Laboratory for Interface Science for Printable Electronic Materials” works on both fundamentals and devices for energy conversion and storage and sensing, including solar cells, transistors, photoelectrodes, transistors, capacitors, and batteries. The group is predominantly experimental and uses a combination of electrochemistry, spectroscopies, microscopies, and synchrotron-based techniques to understand structure-property relationships across time and length scales, with an emphasis on charge transport and charge transfer. Materials of interest include metal halide perovskites, π-conjugated materials, colloidal quantum dots, and metal oxides. Current research and funding includes semiconductor/electrolyte interfaces and durability of printable electronic materials from multiple federal agencies. Such an interdisciplinary group welcomes students and postdocs with training in materials science, chemical engineering, chemistry, and physics, among others.