Copper is a nutrient essential for life. Maintenance of copper balance within cells is key to preserving healthy biological function, with dysregulation of metal-related pathways leading to the development of disease states such as cancer and neurodegeneration.

The Ge Group studies how the proteins in our cells acquire, use, and transport metal ions including copper, and how chemical modifications of these proteins affect their structure and function. Undergraduate summer researchers will contribute to the semi-synthesis of modified copper-binding proteins by performing peptide synthesis, protein expression, and peptide/protein purification.

The purpose of this project is to study the fluorescent properties and photochemistry of thiazolothiazole viologens for solar energy applications. In particular we will study the photoinduced electron transfer events from a donor chromophore to an acceptor thiazolothiazole viologen (TTz). We will monitor these dynamics by studying the fluorescence both of the donor and acceptor molecules.

Read more…

The purpose of this project is to develop novel multifunctional silica-based hybrid nanoparticles with outstanding properties for photodynamic therapy (PDT) and photodynamic inactivation (PDI) applications.

Read more…

The purpose of this project is to develop novel applications of LETs in photonic integrated circuits (PICs).Read more…

The purpose of this project is to computationally design nanomaterials to control the flow of light and heat for energy applications.

Read more…

The goal of this project is to synthesize, characterize, and study the properties of new silicon pincer compounds to enable more efficient organic electronic devices.  Read more…

The goal of this project is to synthesize one-dimensional (1D) oxide nanostructures using chemical vapor deposition (CVD) and study their plasmonic properties for plasmon enhanced photocatalytic applications.Read more…

The goal of this project is to investigate new designing principles for engineering programmable RNA nanoassemblies that can be activated in response to various stimuli and have controllable immunological properties.

Read more…

Despite the existing variety of RNA (and DNA) nanoparticles (NPs) and computational tools for their design, the use of RNA NPs as modular building blocks for constructing RNA networks has never been systematically investigated. To address this need and thereby shift the existing paradigm, the goal of this project is to develop an RNA-based, programmable networking platform that simultaneously encodes targeted biophysical, mechanical, and biochemical properties through networks with multiple independently programmable architectural parameters.

Read more…