Researchers Develop Biocatalyst to Convert Carbon Dioxide into Acetate

TAGS:  Sustainability / Natural Coatings    

NETL researchers develop a biocatalyst with 99% efficiency that can convert carbon dioxide (CO₂), a waste product of fossil energy industries that warms the planet and causes climate change, into acetate, an ingredient used in many products like cleaning supplies, textiles, and as a potential feedstock for biofuels.

Strategy to Meet Net-zero GHG Emission Goal

Deployment of carbon management technologies is crucial to address the climate crisis and meet the administration’s goal of a net-zero greenhouse gas emissions economy by 2050 while protecting existing industrial jobs and creating new ones. Biological conversion of CO₂ is an attractive option to reduce carbon emissions and accelerate work toward a carbon-neutral economy.

Biotechnology approaches have previously relied on photosynthesis, the chemical process that occurs in plants, algae, and some types of bacteria when they are exposed to sunlight and combine water and CO₂ to give off oxygen, to convert CO₂, but that process is less than 4% efficient.

As an alternative that is more efficient than photosynthesis, NETL researchers & inventors Daniel E. Ross, Djuna Gulliver, and Samuel Flett developed a biocatalyst approach to convert CO₂ into acetate. Biocatalysts are natural substances that use enzymes from biological sources to improve the rate of chemical reactions. NETL has filed for a patent on the technology.

Other processes for CO₂ conversion using biocatalysts have been developed, but the biocatalyst developed at NETL has a unique adaptability to feedstocks and resistance to contamination challenges, making it a promising target for large-scale deployment.

Microbes Adapt to Changes in Raw Materials & CO₂

NETL’s Djuna Gulliver, Ph.D., explained that the biocatalyst is made up of a unique microbial community that adapts to changes in the raw materials, CO₂, syngas, formate, and methanol, used in the process as well as other conditions.

“That adaptability makes the biocatalyst very robust to environmental challenges,” Gulliver said. “As a result, the technology is very well suited for widespread field deployment.”

Flett said that adaptability of the NETL biocatalyst approach makes it a good way to convert CO₂ found in waste gas streams from ethanol plants, syngas production and blue hydrogen production, hydrogen produced from natural gas.

Meeting Growing Demand from Paints & Coatings Industry

Ross added that unlike conventional non-biological CO₂ utilization pathways that require high energy and deliver low yields, the NETL biocatalyst technology requires little energy input and converts all CO₂ into a useable product.

Acetate is a particularly attractive product. Growing demand from the paints and coatings industry and flexible packaging sectors are anticipated to be the main driver of market expansion. In addition, acetate’s flexibility and environmental friendliness are driving the market for acetate.

NETL’s carbon conversion research identifies and develops new and improved materials, equipment, and processes that produce value-added goods using CO₂ or CO as a feedstock. Products can include fuels, chemicals, agricultural products, animal feed, building materials and other products.

The development of technologies that lead to revenue-generating products can help support broader carbon emissions reduction strategies and lead to more sustainable power generation and industrial and agricultural practices.

Source: National Energy Technology Laboratory