Inexpensive catalyst uses energy from light to turn ammonia into hydrogen fuel
From: Rice University
November 25, 2022 -- Rice
University researchers have engineered a key light-activated nanomaterial for
the hydrogen economy. Using only inexpensive raw materials, a team from Rice's
Laboratory for Nanophotonics, Syzygy Plasmonics Inc. and Princeton University's
Andlinger Center for Energy and the Environment created a scalable catalyst
that needs only the power of light to convert ammonia into clean-burning
hydrogen fuel.
The research is
published online today in the journal Science.
The research follows
government and industry investment to create infrastructure and markets for
carbon-free liquid ammonia fuel that will not contribute to greenhouse warming.
Liquid ammonia is easy to transport and packs a lot of energy, with one
nitrogen and three hydrogen atoms per molecule. The new catalyst breaks those
molecules into hydrogen gas, a clean-burning fuel, and nitrogen gas, the
largest component of Earth's atmosphere. And unlike traditional catalysts, it
doesn't require heat. Instead, it harvests energy from light, either sunlight
or energy-stingy LEDs.
The pace of chemical
reactions typically increases with temperature, and chemical producers have
capitalized on this for more than a century by applying heat on an industrial
scale. The burning of fossil fuels to raise the temperature of large reaction
vessels by hundreds or thousands of degrees results in an enormous carbon
footprint. Chemical producers also spend billions of dollars each year on
thermocatalysts -- materials that don't react but further speed reactions under
intense heating.
"Transition metals
like iron are typically poor thermocatalysts," said study co-author Naomi
Halas of Rice. "This work shows they can be efficient plasmonic
photocatalysts. It also demonstrates that photocatalysis can be efficiently
performed with inexpensive LED photon sources."
"This discovery
paves the way for sustainable, low-cost hydrogen that could be produced locally
rather than in massive centralized plants," said Peter Nordlander, also a
Rice co-author.
The best
thermocatalysts are made from platinum and related precious metals like
palladium, rhodium and ruthenium. Halas and Nordlander spent years developing
light-activated, or plasmonic, metal nanoparticles. The best of these are also
typically made with precious metals like silver and gold.
Following their 2011
discovery of plasmonic particles that give off short-lived, high-energy
electrons called "hot carriers," they discovered in 2016 that
hot-carrier generators could be married with catalytic particles to produce
hybrid "antenna-reactors," where one part harvested energy from light
and the other part used the energy to drive chemical reactions with surgical
precision.
Halas, Nordlander,
their students and collaborators have worked for years to find non-precious
metal alternatives for both the energy-harvesting and reaction-speeding halves
of antenna reactors. The new study is a culmination of that work. In it, Halas,
Nordlander, Rice alumnus Hossein Robatjazi, Princeton engineer and physical
chemist Emily Carter, and others show that antenna-reactor particles made of
copper and iron are highly efficient at converting ammonia. The copper,
energy-harvesting piece of the particles captures energy from visible light.
"In the absence of
light, the copper-iron catalyst exhibited about 300 times lower reactivity than
copper-ruthenium catalysts, which is not surprising given that ruthenium is a
better thermocatalyst for this reaction," said Robatjazi, a Ph.D. alumnus
from Halas' research group who is now chief scientist at Houston-based Syzygy
Plasmonics. "Under illumination, the copper-iron showed efficiencies and
reactivities that were similar to and comparable with those of
copper-ruthenium.
Syzygy has licensed
Rice's antenna-reactor technology, and the study included scaled-up tests of
the catalyst in the company's commercially available, LED-powered reactors. In
laboratory tests at Rice, the copper-iron catalysts had been illuminated with
lasers. The Syzygy tests showed the catalysts retained their efficiency under
LED illumination and at a scale 500 times larger than lab setup.
"This is the first
report in the scientific literature to show that photocatalysis with LEDs can
produce gram-scale quantities of hydrogen gas from ammonia," Halas said.
"This opens the door to entirely replace precious metals in plasmonic
photocatalysis."
"Given their
potential for significantly reducing chemical sector carbon emissions,
plasmonic antenna-reactor photocatalysts are worthy of further study,"
Carter added. "These results are a great motivator. They suggest it is
likely that other combinations of abundant metals could be used as
cost-effective catalysts for a wide range of chemical reactions."
Halas is Rice's Stanley
C. Moore Professor of Electrical and Computer Engineering and a professor of
chemistry, bioengineering, physics and astronomy, and materials science and
nanoengineering. Nordlander is Rice's Wiess Chair and Professor of Physics and
Astronomy, and professor of electrical and computer engineering, and materials
science and nanoengineering. Carter is Princeton's Gerhard R. Andlinger
Professor in Energy and Environment at the Andlinger Center for Energy and the
Environment, senior strategic adviser for sustainability science at the
Princeton Plasma Physics Laboratory, and professor of mechanical and aerospace
engineering and of applied and computational mathematics. Robatjazi is also an
adjunct professor of chemistry at Rice.
Halas and Nordlander
are Syzygy co-founders and hold an equity stake in the company.
The research was
supported by the Welch Foundation (C-1220, C-1222), the Air Force Office of
Scientific Research (FA9550-15-1-0022), Syzygy Plasmonics, the Department of
Defense and Princeton University.
Additional co-authors
include Yigao Yuan, Jingyi Zhou, Aaron Bales, Lin Yuan, Minghe Lou and Minhan
Lou of Rice, Linan Zhou of both Rice and South China University of Technology,
Suman Khatiwada of Syzygy Plasmonics, and Junwei Lucas Bao of both Princeton
and Boston College.
https://www.sciencedaily.com/releases/2022/11/221125132041.htm
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