<![CDATA[Georgia Tech Awarded $11.2 Million Grant for Energy Frontier Research Center]]> 27869 Georgia Tech receives an $11.2 million grant from the U.S Department of Energy to fund a multi-institution research center led by The School of Chemical & Biomolecular Engineering (ChBE). The Center for Understanding and Control of Acid Gas-Induced Evolution of Materials for Energy (UNCAGE-ME) is one of only 10 new Energy Frontier Research Centers (EFRCs) to be funded through the federal program and is the first EFRC to be led by Georgia Tech. Krista Walton, a ChBE professor, will serve as director for the center, which aims to advance the understanding of how acid gases interact with wide range of energy-related materials.

 “The overall goal of our EFRC is to provide a fundamental understanding of acid gas interactions with a broad class of materials and establish strategies for extending material stability and lifetime,” Walton said. “These results will ultimately enable us to accelerate materials discovery for large-scale energy applications.

Five other ChBE professors — Christopher Jones, Michael Filler, Ryan Lively, Sankar Nair and David Sholl, and Thomas Orlando, a professor in the Georgia Tech School of Chemistry and Biochemistry — also will serve as principal investigators at the center. The center will involve work at six partner institutions: Oak Ridge National Laboratory (Oak Ridge, Tenn.; the Department of Energy’s largest multiprogram science and energy laboratory), the University of Florida, the University of Alabama, the University of Wisconsin, Lehigh University (Bethlehem, Pa.) and Washington University in St. Louis.

 “Our multifaceted approach to this important problem is unique, and one of our proposal reviewers even pointed out that this will be the first research center in the world specifically dedicated to this topic, said Walton.”

 The research center’s start date is Aug. 1. The awards announced on June 18 are the second round of funding for EFRCs. The 32 projects receiving funding were competitively selected from more than 200 proposals. 

For more information about the EFRC program, click here.

]]> Allison Caughey 1 1403530917 2014-06-23 13:41:57 1475896597 2016-10-08 03:16:37 0 0 news 2014-06-23T00:00:00-04:00 2014-06-23T00:00:00-04:00 2014-06-23 00:00:00 304591 304591 image <![CDATA[Krista Walton]]> image/jpeg 1449244637 2015-12-04 15:57:17 1475895009 2016-10-08 02:50:09 <![CDATA[Professor Meilin Liu Awarded $1M Grant from U.S. Department of Energy to Develop New Fuel Cell Technology]]> 27869 Meilin Liu, Regents' Professor and Associate Chair in the School of Materials Science and Engineering, has received a prestigious Advanced Research Projects Agency-Energy (ARPA-E) grant from the U.S. Department of Energy (DOE) to expand work with fuel cells. ARPA-E’s new Reliable Electricity Based on Electrochemical Systems (REBELS) program, recognizes researchers with high-potential, high-impact, pre-commercial projects in fuel cell technologies for distributed power systems. Dr. Liu’s project utilizes methane, a cheap and abundant natural gas, to develop more efficient, lower-temperature and cost-effective fuel cells for grid-level power-generation. Liu’s project was awarded $1 million and was one of only 13 new projects selected nationwide.

“Georgia Tech has a long-standing reputation for excellence in materials science and engineering,” said Materials Science and Engineering School Chair Dr. Naresh Thadhani. “Dr. Liu’s ARPA-E project presents an exciting opportunity for our program to have an even broader impact in solving challenges of great societal importance.”

Fuel cells convert the chemical energy of a fuel source into electrical energy and are optimal for distributed power generation systems, which generate power close to where it is used. Though fuel cells have been viewed as a potential eco-friendly alternative to fossil fuels, durability, performance, and cost have been barriers to widespread commercial use of fuel cells. Over the last decade, research advances have improved many of the materials and engineering challenges contributing to fuel cells’ cost and performance issues. But these research efforts have been primarily focused on exploring technologies that either operate at high temperatures (600°C or higher) for grid-scale applications or low temperatures (180°C) for vehicle technologies.

Liu’s project will focus on developing fuel cell devices that operate in an intermediate temperature range (200-500°C). The fuel cells will directly process methane and will use nanocomposite electrolytes that enable the fuel cells to operate at lower temperatures and utilize lower-cost materials to produce, store, and distribute power. Designed for household application, the fuel cells offer a viable low-cost, high-performance solution for mass distributed power generation and storage.

 “Methane fuel cells are particularly well-suited for household use because homes are already equipped to run on natural gas,” said Liu. “The fuel cell would just replace the water heater or furnace and enable families to power their homes without connecting to the grid, which offers a cleaner, more efficient energy option.”

Tim Lieuwen, director of the Strategic Energy Institute, said distributed power generation solutions such as Liu’s offer great promise in mitigating many of the challenges associated centralized generation.

“In our current centralized approach, electricity is primarily produced at large generation facilities and often require long transmission distances that can result in power losses and leave lines vulnerable to disruption during inclement weather or natural disasters,” said Lieuwen.

Liu is also a collaborator on another ARPA-E fuel cell project with The University of California – Los Angeles.

 

]]> Allison Caughey 1 1403531494 2014-06-23 13:51:34 1475896597 2016-10-08 03:16:37 0 0 news 2014-06-23T00:00:00-04:00 2014-06-23T00:00:00-04:00 2014-06-23 00:00:00 68420 68420 image <![CDATA[Meilin Liu with fuel cell]]> 1449177176 2015-12-03 21:12:56 1475894594 2016-10-08 02:43:14