The
CO2 to hydrocarbon conversion process using different
strategies. Credit: Nature Energy (2025). DOI: 10.1038/s41560-025-01883-w
Carbon
dioxide (CO2) is one
of the world's most abundant pollutants and a key driver of climate change. To
mitigate its impact, researchers around the world are exploring ways to capture
CO2 from
the atmosphere and transform it into valuable products, such as clean fuels or
plastics. While the idea holds great promise, turning it into reality—at least
on a large scale—remains a scientific challenge.
A new study led by Smith Engineering
researcher Cao Thang Dinh (Chemical Engineering), Canada Research Chair in
Sustainable Fuels and Chemicals, paves the way to practical applications of
carbon conversion technologies and may reshape how we design future carbon
conversion systems. The research addresses one of the main roadblocks in the
carbon conversion
process: catalyst stability.
In chemical engineering, a catalyst is a
substance that accelerates a reaction—ideally, without being consumed in the
process. In the case of carbon conversion, catalysts play a critical role by
enabling the transformation of CO₂ into useful products such as fuels and building
blocks for sustainable materials.
Copper-based materials are the most
efficient catalysts for converting CO2 into methane, the main component of the natural
gas used in water and home heaters, and for electricity generation. However,
these copper catalysts undergo significant transformation in the process, and
keeping the system working for a long period of time remains critically
challenging.
Dr. Dinh's team has developed an
innovative method to synthesize and recycle the copper catalyst during the
electrochemical reaction within the carbon conversion system. These
exciting results were recently published in Nature
Energy.
In
this approach, what is added to the system is not the copper catalyst per se,
but a catalyst precursor (a substance that requires activation to become an
active catalyst). Researchers then use electrical signals to dynamically form
catalysts in situ during the CO2 conversion process.
What's better: when electric signals are
turned off, the catalyst goes back to its precursor form. "Repeating this
cycle ensures selective and stable performance over extended periods. This is
one of the most stable systems for carbon conversion to date," says Dr.
Dinh.
In traditional carbon conversion
systems, once the CO2 reduction
reaction gets started, it needs to keep running to avoid catalyst degradation.
But in the new system, when the reaction stops, the catalyst turns back into
its precursor form. Once the system is turned back on, in a matter of seconds,
it produces a new catalyst and restarts the carbon reduction reaction.
Stability during intermittent operations
is crucial for integrating carbon conversion systems and intermittent renewable
energy sources, like solar or wind power. Dr. Dinh and the team are energized
about the new possibilities these findings present, especially for the
production of methane.
"Methane has a remarkably high
energy density, which is important for energy storage applications," says
Guorui Gao, a Ph.D. student working on the project. "The seamless
compatibility with existing gas infrastructure, including transportation
pipelines and storage facilities, makes it suited for large-scale and long-term
energy solutions."
The research involves collaboration from
multiple institutions from Canada, the United States, Brazil, Spain and
Australia. As a next step, Dr. Dinh's lab will attempt to apply this same
process to produce ethylene, ethanol, and other products. The team will also
work to scale up the technology to prepare it for practical applications,
paving the way for a more sustainable future.
Source: Turning pollution into clean fuel with stable methane production from carbon dioxide
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