Scientists Produce Acetylene from CO₂ and Water Using Carbon Capture Technology

TAGS:  PVC, Plasticizers and Sustainability     Sustainability / Natural Solutions    

Researchers from Japan have developed an innovative electrochemical technique to produce acetylene using carbon dioxide and water as raw materials.

This method could greatly reduce the carbon footprint of acetylene synthesis and contribute to sustainable carbon capture technologies.

Essential Raw Material for PVC and Resins

Acetylene is an essential precursor in the production of resins and plastics such as PVC, as well as a useful gas in many industrial processes. However, its synthesis requires fossil fuels, making it environmentally taxing.

Reaching sustainability is one of humanity’s most pressing challenges today—and also one of the hardest. To minimize our impact on the environment and start reverting the damage humanity has already caused, striving to achieve carbon neutrality in as many economic activities as possible is paramount. Unfortunately, the synthesis of many important chemicals still causes high carbon emissions.

Such is the case with acetylene (C₂H₂), an essential hydrocarbon with a plethora of applications. This highly flammable gas is used for welding, industrial cutting, metal hardening, heat treatments, and other industrial processes. In addition, it is an important precursor in the production of synthetic resins and plastics, including PVC. Since the production of C₂H₂ requires fossil fuels as feedstock, a more environmentally friendly synthesis route is urgently needed.

Based on Electrochemical Conversion of CO₂

Against this backdrop, a research team based on an academia–industry collaboration between Doshisha University and Daikin Industries, Japan, has been developing a new and very promising strategy to produce C2H2 using carbon dioxide (CO₂) and water (H₂O) as raw materials.

The proposed approach is based on the electrochemical and chemical conversion of CO₂ into C₂H₂ by using high-temperature molten salts, namely chloride melts. One key aspect of the process is that it leverages metal carbides, which are solids composed of carbon atoms and metal atoms, as a pivot point in the conversion. “In our strategy, CO₂ is first converted to metallic carbides such as CaC₂ and Li₂C₂, which deposit onto one of the electrodes,” explains Dr. Suzuki. “Then, these metal carbides react with H₂O, generating C₂H₂ gas.”

To achieve higher energy efficiency out of this method, the team had to test various configurations, including different electrode materials and molten salt compositions. After a series of comprehensive experiments, including cyclic voltammetry, carbon crystallinity analysis, and X-ray diffraction, they determined that a NaCl−KCl−CaCl₂−CaO melt saturated with additional CaCl₂ in a CO₂ atmosphere yielded the best results. This particular melt led to the selective formation of CaC₂ around the cathode, which achieved better results than melts including lithium.

Directly Utilizing CO₂ as Feedstock

This innovative strategy offers important advantages over conventional synthesis pathways for C₂H₂. First, the electrodes can be reused after a simple reconditioning treatment since the desired reaction occurs on the deposited metal carbides rather than directly on the electrode surfaces. Another advantage, and perhaps the most notable, is the direct use of CO₂ as feedstock to produce an industrially useful and valuable chemical.

“The proposed approach represents a promising technology for realizing a sustainable resource and energy cycle without relying on fossil fuels,” highlights Prof. Goto. Adding further, he says, “In the future, this same technique could be used as a carbon negative emission technology by extracting carbon dioxide from the air and using it as a raw material, particularly in combination with direct air capture processes.”

With any luck, further research on this exciting method will lead to both economically and environmentally viable ways to produce important resins and chemicals from CO₂, paving the way to sustainable societies. Ultimately, these efforts would enable us to live in harmony with the environment while maintaining many of the positive aspects of our modern way of life.

Source: Doshisha University