Aluminum nanoparticles make tunable green catalysts
Catalysts unlock pathways for chemical reactions to unfold at faster and more efficient rates, and the development of new catalytic technologies is a critical part of the green energy transition.
The Rice University lab of nanotechnology pioneer Naomi Halas has uncovered a transformative approach to harnessing the catalytic power of aluminum nanoparticles by annealing them in various gas atmospheres at high temperatures.
According to a study published in the Proceedings of the National Academy of Sciences, Rice researchers and collaborators showed that changing the structure of the oxide layer that coats the particles modifies their catalytic properties, making them a versatile tool that can be tailored to suit the needs of different contexts of use from the production of sustainable fuels to water-based reactions.
"Aluminum is an earth-abundant metal used in many structural and technological applications," said Aaron Bayles, a Rice doctoral alum who is a lead author on the paper. "All aluminum is coated with a surface oxide, and until now we did not know what the structure of this native oxide layer on the nanoparticles was. This has been a limiting factor preventing the widespread application of aluminum nanoparticles."
Aluminum nanoparticles absorb and scatter light with remarkable efficiency due to surface plasmon resonance, a phenomenon that describes the collective oscillation of electrons on the metal surface in response to light of specific wavelengths. Like other plasmonic nanoparticles, the aluminum nanocrystal core can function as a nanoscale optical antenna, making it a promising catalyst for light-based reactions.
"Almost every chemical, every plastic that we use on a day-to-day basis, came from a catalytic process, and many of these catalytic processes rely on precious metals like platinum, rhodium, ruthenium and others," Bayles said.
"Our ultimate goal is to revolutionize catalysis, making it more accessible, efficient and environmentally friendly," said Halas, who is a University Professor, Rice's highest academic rank. "By harnessing the potential of plasmonic photocatalysis, we're paving the way for a brighter, more sustainable future."
The Halas group has been developing aluminum nanoparticles for plasmonic photocatalysis reactions such as decomposition of dangerous chemical warfare agents and efficient production of commodity chemicals. The newly uncovered ability to modify the surface oxides on aluminum nanoparticles further increases their versatility for use as catalysts to efficiently convert light into chemical energy.
"If you're doing a catalytic reaction, the molecules of the substance you're looking to transform will interact with the aluminum oxide layer rather than with the aluminum metal core, but that metallic nanocrystal core is uniquely able to absorb light very efficiently and convert it into energy, while the oxide layer fulfills the role of a reactor, transferring that energy to reactant molecules," Bayles said.
More information: Aaron Bayles et al, Tailoring the aluminum nanocrystal surface oxide for all-aluminum-based antenna-reactor plasmonic photocatalysts, Proceedings of the National Academy of Sciences (2024). DOI: 10.1073/pnas.2321852121
Journal information: Proceedings of the National Academy of Sciences
Provided by Rice University