Report highlights need for better carbon storage technology

Eve Pope, Technology Analyst at IDTechEx, explains how carbon capture technologies can be made more efficient. Read on: 

Carbon capture technologies capable of removing CO₂ from industrial emissions have been around for over 50 years, but widescale deployment of CCUS (carbon capture, utilisation, and storage) has been too slow for global net-zero ambitions. While governments are beginning to implement carbon pricing mechanisms or tax credits to motivate permanent storage of CO2 deep underground, a profitable business model exists beyond CO₂ sequestration via emerging CO₂ utilisation applications. According to the new IDTechEx research report, “Carbon Dioxide Utilisation 2025-2045: Technologies, Market Forecasts, and Players”, sales from CO₂ utilisation will directly generate US$240bn in revenue in 2045.

Carbon dioxide utilisation technologies recycle captured CO₂. The new carbon-containing products can be sold to generate financial benefits while offering a reduction in carbon footprint. The leading fate of captured carbon dioxide today is enhanced oil recovery - a method of reversing productivity decline in depleted oil fields. However, there are many emerging areas of CO₂ recycling, including CO₂-derived concrete, CO₂-derived fuels (methane, methanol, kerosene, diesel, and gasoline), CO₂-derived chemicals, and CO₂ yield boosting applications (crop greenhouses, algae, and proteins).

Profitable chemicals

Profitable production of CO₂-derived polymers has been around for decades. Asahi Kasei pioneered production of polycarbonate from waste CO₂ in 2002. The total annual production capacity of polycarbonate resin using CO2 utilisation technology has now reached about 1 million tonnes. Other essential plastics, such as polyethylene and PET, are starting to be made from CO2 via thermochemical and biological conversion routes, with LanzaTech leading microbial innovation in this space. Drop-in chemicals such as CO₂-derived ethanol and aromatics are also being commercialised.

While potentially all carbon-containing chemicals could utilise carbon dioxide in production, those requiring non-reductive pathways are the most promising due to a smaller energy demand and lack of dependency on low-carbon hydrogen production. The new IDTechEx report “Carbon Dioxide Utilisation 2025-2045: Technologies, Market Forecasts, and Players” explores synthesis routes for chemical companies to use waste CO2 as a green feedstock, displacing petrochemical products.

Decarbonising the aviation and shipping sectors

To date, alternative fuels have not achieved price parity with fossil fuels, inhibiting market uptake. However, increased market penetration of CO₂-derived fuels is expected to come from regulations already being put in place, such as fuel-blend mandates for long-haul transportation. As green hydrogen electrolyzer capacity scales up worldwide, production of e-fuels from carbon dioxide using power-to-x technology will also increase. These fuels are expected to play a role in decarbonising shipping and aviation as full electrification of the aviation and maritime sectors is currently unfeasible.

Several CO₂-derived fuels are already being commercially produced with many more commercial facilities expected over the next decade. The start of 2024 saw Mitsui and Celanese’s joint venture Fairway Methanol become operational, joining plants from Carbon Recycling International in producing over 100,000 tonnes per year of methanol made from captured CO₂. Other hydrocarbon fuels such as kerosene, diesel, and gasoline, which can be made via methanol or syngas intermediates, are also being ramped up. For example, Infinium’s Corpus Facility opened its doors this year, expected to produce thousands of tonnes per annum of CO2-derived e-fuels.

A net-negative future

The new IDTechEx report “Carbon Dioxide Utilisation 2025-2045: Technologies, Market Forecasts, and Players”, covers how CO₂ utilisation can lower the carbon footprint of ready-mixed concrete, precast concrete, and carbonate aggregates/supplementary cementitious materials through CO2 mineralisation reactions. Players already utilising over 10,000 tonnes of carbon dioxide each year in carbonates include O.C.O Technology and Greenore.

When CO₂ is permanently stored in concrete, performance is improved, and less cement is needed. Growth of CO₂-derived building materials will be driven by new certifications, superior materials performance, and the ability to achieve price parity through waste disposal fees and the sale of carbon credits.