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electrolysis

CO2 Conversion Technology for Sustainable Carbon Materials

Bergen Carbon Solutions is a company transforming CO2 into a valuable resource by using renewable energy to convert excess greenhouse gas into solid, versatile industrial raw materials. The carbon capture and utilization (CCU) technology developed by Bergen has the potential to deliver a stable supply of carbon nanotubes and graphite, and also reduce manufacturers' exposure to geopolitical risks associated with raw material sourcing.

Battolyser®

Battolyser® is a novel technology that combines the functionality of a battery and an electrolyzer in a single, patented system. It efficiently stores and supplies power like a battery while also splitting water into hydrogen and oxygen when fully charged. This dual-functionality makes Battolyser® a highly versatile and efficient energy solution, capable of switching smoothly between power storage and hydrogen production.

eFuels From Waste CO2 and Hydrogen

Infinium produces electrofuels (eFuels) to help the heavy transit and chemicals sectors achieve net zero by reducing CO2 emissions. Infinium eFuels are made from green hydrogen derived from renewable power and captured carbon dioxide in a proprietary process developed and commercialized over a decade. Infinium’s unique production process facilitates the on-site production of ultra-low carbon transportation fuels and chemicals such as sustainable aviation fuels (eSAF), eDiesel, and eNaphtha.

Upcycling Sulfate Byproducts Into Carbon-Negative Sulfuric Acid and Green Hydrogen - The Travertine Process

The Travertine process converts aqueous sulfate into sulfuric acid and caustic solutions through electrolysis, generating clean and competitively priced hydrogen. The process involves three primary units. Initially, electrolysis divides aqueous sulfate into sulfuric acid and caustic solutions. Subsequently, Direct Air Capture (DAC) utilizes the caustic solution to extract CO2 from the air, yielding a carbonate solution. Lastly, the carbonate solution reacts with sulfate byproducts to form minerals and regenerate aqueous sulfate through mineralization.