Fijishi AI for Carbon Capturing Microbes.

The large-scale deployment of microbial carbon capture systems may eventually contribute in a significant way to achieving net-zero emissions. Companies could, once implemented, generate new products for the market instead of paying between $50 and $100 per tonne of CO2 to offset their emissions.

Climate change...

Amid the urgency of climate change, Aeterna AI for microorganisms is being used to capture greenhouse gases from air or exhaust gases and converting them into high-value products. Engineering the organisms promises a wide palette of sustainable products while reducing global warming. Simultaneously, it produces various products with significant market potential, such as fuels, fertilizers and animal feed.

Engineering organisms to convert emissions into valuable product.

Microorganisms engineered to capture carbon using Aeterna AI convert greenhouse gases into valuable products like fuels and fertilizers.

Cell modification...

Aeterna AI is used by organizations specializing in cell modification to boost specific substance production. The product value of photobioreactors & hydrogen, organic waste streams or other chemicals derived from CO2 varies significantly; the choice between which system to use may vary on the specific needs and capabilities of the implementing company, such as available resources.

Aeterna AI use - cases for AI for carbon - capturing microbes.

Support for a Renewable Energy Transition - Aeterna for Microorganisms help turn CO2 into a source of sustainable energy.

Aeterna for Microorganisms have a key role to play in the transition away from fossil fuels. Using them to produce alternative biomaterials means boosting sustainability and efficient energy use. Aeterna for Microbial Carbon Dioxide Capture and Utilization (MCCU) leverages microbes to transform CO2 into usable biomass, biofuels, and even electricity. This cuts carbon dioxide emissions while boosting renewable energy production. Meanwhile Aeterna for Microbial Electrosynthesis (MES) utilizes renewable electricity from sources like solar, wind, geothermal, and biomass to power the conversion of CO2 into valuable organic compounds. Both approaches help prompt an energy economy based on natural processes such as solar and wind cycles, which are renewable and maintain the planet’s ecological balance. They continuously replenish, without depleting natural resources - thereby increasing the odds of a sustainable energy future.

Supporting a Low-Carbon Economy - Selling bioenergy products converted by Aeterna for microorganisms help pay for carbon capture systems.

Aeterna for Microbial systems underpin the low-carbon economy of the future, ensuring our independence from fossil fuels. By using solar energy, microorganisms convert carbon dioxide into forms of bioenergy like biomethane, biodiesel, and bioethanol - through photosynthesis or other metabolic processes - and the sale of these bioenergy products can then help offset the high cost of deploying carbon capture techniques. Taking advantage of Aeterna for microorganisms' ability to use CO2 foster more environmentally friendly and sustainable industrial processes, particularly in fields like chemical engineering and waste treatment. Microbial systems also facilitate the accumulation of organic carbon and the mineralization of CO2 in soil, while accelerating the rate of photosynthesis of CO2 to organic matter in water.

Industrial Decarbonization - Capturing CO2 from industrial exhaust gas with multiple benefits.

Industrial decarbonization is critical. Aeterna for Microbial systems play a key role, by capturing carbon dioxide from industrial emissions and transforming them into renewable biofuels that are fossil fuel alternatives, like biogas and biohydrogen, through processes like microbial anaerobic digestion and dark fermentation. Microbial systems capture carbon dioxide either directly from the atmosphere or industrial emissions, and convert it into bicarbonate ions; over time, these transform into stable carbonate minerals that are deposited as rocks. This effectively locks away carbon in a solid, stable form - and carbonates are used to produce building materials like cement. In addition, microbial systems play a vital role in treating organic waste from industrial processes, by generating hydrogen from wastewater in ways that reduce wastewater treatment costs and carbon emissions.

Generate new
products.

Aeterna AI or microbial carbon capture is a potentially powerful means to manage atmospheric carbon dioxide levels, and curb global warming. It help’ reduce greenhouse gases while spurring the production of valuable commodities like biofuels, fertilizers, and animal feed. To help make it a sustainable, economically viable reality, researchers are continuously developing microorganisms – including bacteria and microalgae – that use sunlight or sustainable chemical energy to absorb and transform gases.

Top countries by business & academic using Aeterna AI for High Altitude Platform Stations - Canada, Iceland, Australia, Germany, Switzerland.

Top industries by business & academic using Aeterna AI for High Altitude Platform Stations - Environment, Agriculture, Energy, Healthcare.

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