Program for Advancing Collaborative Teams
Program for Advancing Collaborative Teams (PACT)
The Science Alliance was formed to build and enhance relationships between University of Tennessee, Knoxville (UT) faculty and Oak Ridge National Laboratory (ORNL) scientists and engineers. In keeping with this rich history, the Science Alliance implemented the Program for Advancing Collaborative Teams (PACT) program to provide support for collaborative research endeavors aimed at securing large extramural funding, such as NSF Materials Research Science and Engineering Centers (MRSEC) or NIH RM1 grants. Calls for this program will be made approximately 15 months before the anticipated submission of an external proposal. Investigator-identified opportunities will also be considered, if they are brought to the attention of Science Alliance with sufficient lead time to issue a university wide call. Typical awards will be $100-200k, and 2-3 awards are expected to be made. Projects will have staged funding for one year as long as performance metrics are achieved. A chance for second year funding will also be available if the project shows strong promise of receiving new external funding as a result of the collaborative activities and is deemed meritorious in the second year ‘s proposal evaluation process.
Dayakar Penumadu – 2023
Hypersonic technologies have been investigated in the past for reusable applications such as space shuttles. Today, new classes of hypersonic weapons capabilities are emerging throughout the world and there is an urgent need to develop a new class of materials needed to satisfy extreme environment to be experienced related to temperature, mechanical loading, and plasma driven environment exposing material surfaces to atomic oxygen and nitrogen. We propose to develop novel materials, carbon matrix composites with carbon fiber reinforcement that can consider a variety of fiber architecture and high carbon resins for conversion with improved throughput.
Nicole McFarlane – 2022
Toward Hybrid Biomicroelectronic Systems
Biological systems have been shown to be much more efficient at sensing, processing, and communicating data. However, while there are many different tools to monitor these systems there is little work developing systems which form a closed loop between the biology and the electronics to create hybrid biomicroelectronic systems. McFarlane’s goal is to investigate these hybrid systems and develop of means of engineering cellular expression within them.