Process performance validated for key components; now scaling up
Monmouth Junction, NJ - Liquid Light unveiled its new process for the production of major chemicals from carbon dioxide (CO2), showcasing its demonstration-scale ‘reaction cell’ and confirming the potential for cost-advantaged process economics. Because carbon dioxide — a greenhouse gas — is low-cost and readily available worldwide, Liquid Light’s customers can profit by producing high-value chemicals from CO2 ‘waste’; reduce their dependence on oil; and potentially reduce their carbon footprint.
Liquid Light’s first process is for the production of ethylene glycol (MEG), with a $27 billion annual market, which is used to make a wide range of consumer products such as plastic bottles, antifreeze and polyester clothing. Liquid Light’s technology can be used to produce more than 60 chemicals with large existing markets, including propylene, isopropanol, methyl-methacrylate and acetic acid.
Making electrocatalytics practical for harnessing carbon dioxide as an alternative feedstock
Liquid Light’s core technology is centered on low-energy catalytic electrochemistry to convert CO2 to chemicals, combined with hydrogenation and purification operations. By adjusting the design of their catalyst, Liquid Light can produce a range of commercially important multi-carbon chemicals. Additionally, by using ‘co-feedstocks’ along with CO2, a plant built with Liquid Light’s technology may produce multiple products simultaneously.
Liquid Light’s advances that enable commercialization include the development of long-lasting catalyst components; the ability to run continuously for extended times; and major progress in energy efficiency.
Promising economics from low-cost feedstock and proven-efficient process
Results to date highlight promising economics in three key dimensions:
Liquid Light’s process: Reduction in carbon footprint for chemical production
Liquid Light’s process also reduces the overall carbon footprint for chemical production compared to conventional methods, when powered with electricity produced from natural gas, nuclear, advanced coal and renewable sources. Further, Liquid Light’s process can sequester carbon – meaning it is a net reducer of carbon in the environment – when using energy sources like solar, hydro, wind or nuclear power. To further demonstrate this potential benefit, the company also showed the process can be powered by intermittently-available renewable energy sources like solar and wind. The result is that chemicals can be made directly from renewable energy sources and CO2.
“We’re delighted to be introducing a new and valuable alternative for the mainstream chemical industry,” said Kyle Teamey, CEO of Liquid Light. “Liquid Light’s technology offers a new and cost-effective way to make everyday products from plain old carbon dioxide. This is a great way to reduce our dependence on fossil fuels while we simultaneously consume an environmental pollutant.”
About Liquid Light
Liquid Light develops and licenses process technology to make major chemicals from low-cost, globally-abundant carbon dioxide (CO2). Customers profit from a lower cost of production, while harnessing their current waste stream; reduce their dependence on cyclically-priced petroleum feedstocks; and can reduce their carbon footprint.
Liquid Light’s first process is for the production of ethylene glycol (MEG), with a $27 billion annual market. Results consistent with cost-advantaged production have been validated at lab scale for key parts of our process; and the process scales in a predictable manner, akin to world-scale chlor-alkali plants.
Liquid Light’s core technology is centered on low-energy catalytic electrochemistry to convert CO2 to multi-carbon chemicals. It is backed by more than 100 patents and applications, and extends to multiple chemicals with large existing markets, including ethylene glycol, propylene, isopropanol, methyl-methacrylate and acetic acid.
Liquid Light's investors include VantagePoint Capital Partners, BP Ventures, Chrysalix Energy Venture Capital, and Osage University Partners.
For more information:
For Liquid Light: Rob Adler, email@example.com, 415.984.1970 x0104