Understanding structure-activity relationships in disordered (oxy)hydroxide electrocatalys — NSF Award to University of Texas at A
Hydrogen is a promising low- to zero-carbon resource and could pave the way to a clean energy economy across multiple sectors, including chemical manufacturing, agriculture, and transportation. Electrocatalysis is at the forefront of technologies that could help realize a hydrogen economy at scale. Earth-abundant, low-
| Award title | Understanding structure-activity relationships in disordered (oxy)hydroxide electrocatalys |
|---|---|
| Award ID | 2516042 |
| Awardee | University of Texas at Austin |
| City | AUSTIN |
| State | TX |
| Amount obligated | $533,612 |
| Principal investigator | Wennie Wang |
| Program | Catalysis |
| Start date | 08/15/2025 |
| Abstract | Hydrogen is a promising low- to zero-carbon resource and could pave the way to a clean energy economy across multiple sectors, including chemical manufacturing, agriculture, and transportation. Electrocatalysis is at the forefront of technologies that could help realize a hydrogen economy at scale. Earth-abundant, low-cost electrocatalysts that help chemically split water into hydrogen and oxygen are a promising platform for hydrogen generation. A major challenge is that electrocatalysts often u |
| Source | NSF Awards |
$799/mo
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