1646
(Invited) HydroGEN: An AWSM Energy Materials Network

Monday, 14 May 2018: 13:35
Room 606 (Washington State Convention Center)
J. W. Vickers (U.S. Department of Energy), H. N. Dinh (National Renewable Energy Laboratory), K. Randolph (U.S. Department of Energy), A. Z. Weber (Lawrence Berkeley National Laboratory), A. H. McDaniel (Sandia National Labs), R. Boardman (Idaho National Laboratory), T. Ogitsu (Lawrence Livermore National Laboratory), H. Colon-Mercado (Savannah River National Laboratory), D. Peterson, and E. L. Miller (U.S. Department of Energy)
The Energy Materials Network (EMN) is a Department of Energy (DOE) network of national lab-led consortium aimed at accelerating the development and commercial deployment of novel materials by enhancing the accessibility of unique material research resources at the national laboratories to external stakeholders, such as academia and industry. The HydroGEN EMN was launched in October 2016 by the DOE Office of Energy Efficiency and Renewable Energy (EERE) Fuel Cell Technologies Office (FCTO).

HydroGEN (https://www.h2awsm.org/) EMN is a six-lab consortium, led by the National Renewable Energy Laboratory (NREL). It currently comprises six core national laboratories: NREL, Sandia National Laboratory (SNL), Lawrence Berkeley National Laboratory (LBNL), Idaho National Laboratory (INL), Lawrence Livermore National Laboratory (LLNL), and Savannah River National Laboratory (SRNL). HydroGEN aims to accelerate the discovery and development advanced water splitting materials (AWSM) for sustainable, large-scale hydrogen production, in order to more effectively enable the widespread commercialization of hydrogen and fuel cell technologies. With the rollouts of fuel cell electric vehicles (FCEVs) by major automotive manufacturers underway, enabling AWS technologies for the widespread production of affordable, sustainable hydrogen becomes increasingly important.

Hydrogen is a unique energy carrier in that it can be produced from a number of diverse pathways, utilizing a variety of domestically available feedstocks, including natural gas, biomass, and water. Advanced water splitting (AWS) technologies, including advanced electrolysis (low and high temperature), photoelectrochecmical (PEC) and solar thermochemical (STCH) routes, are some of the more versatile pathways, and will play a significant role in long-term, high volume sustainable production.

The HydroGEN Consortium offers an extensive collection of materials research capabilities for addressing RD&D challenges in efficiency, durability and cost. Leveraging the HydroGEN Consortium’s staff of leading technical experts and broad collection of resource capabilities is expected to advance the maturity and technology readiness levels in all the advanced water splitting technologies. In June 2017, DOE EERE FCTO announced the award of 18 new HydroGEN seedling projects, and one project focused on benchmarking advanced water splitting technologies. These 19 new projects utilized 44 unique capabilities across the six HydroGEN core labs. Furthermore, it is a nationwide R&D effort that comprises 10 national labs, 6 companies, and 22 universities. This presentation will provide an overview of the HydroGEN EMN consortium and highlight some of the advanced water electrolysis projects that are focused on hydrogen and oxygen evolution catalysis.