Breakthrough Process Biocatalytic
Some of the Known Approaches for CO2 to fuel recycling include (1) Direct photolysis qui intense uses light energy to break off the oxygen Atoms in CO2, and (2) chemically Reacting carbon dioxide gas (CO2) with hydrogen gas (H2) to create methane or methanol. Both of These Approaches conventional engineering require huge energy due to high pressure and high temperature chemical processes. For some applications Such As military and space, the high cost of These technologies May be justifiable. HOWEVER, we do not believe thesis Approaches will be economically viable in Creating transportation fuels for global consumption.
By innovating at the intersection of chemical engineering and bio-engineering, we-have Discovered has low energy and highly scalable process to recycle wide quantities of CO2 into gaseous and liquid fuels using organic biocatalysts. The key to our CO2-to-Fuel approach lies in a proprietary multi-step biocatalytic process. Instead of using expensive inorganic Catalysts, Such As zinc, gold or zeolite, with traditional high energy chemical catalytic processes, our process uses inexpensive, renewable biomolecules to catalyze some chemical reactions required to transform CO2 and water (H2O) into fuel molecules. Of greatest significance, our process OCCURS at low temperature and low pressure, thereby Requiring far less energy than --other Approaches.
The energy efficient biocatalytic processes we are exploiting in our technology Actually Occur in certain micro-organisms Where Carbon Atoms, Extracted from CO2, and hydrogen Atoms, Extracted from H2O, are combined to create hydrocarbon molecules. Our breakthrough technology allows processes to operate thesis was very large industrial scale through advance nano-engineering of the biocatalysts and highly efficient process design.
Here is the translation "google improved by bibi":
major breakthrough in biocatalysis
Some of the known approaches for cracking and recycling CO2 are (1) direct photolysis which uses intense light energy to extract oxygen atoms in CO2, and (2) chemically react carbon dioxide (CO2) and hydrogen (H2) to create methane or methanol. Both of these classical technical approaches require great energy due to high pressure and high temperature chemical processes. For some applications such as military and space, the high cost of these technologies is justifiable. However, we do not believe that these approaches will be economically viable for creating "consumer" fuels.
By innovating at the intersection of chemical engineering and bioengineering, we have discovered a low-energy method to recycle large amounts of CO2 using biocatalysts. The key to our method lies in a biocatalytic process. Instead of using expensive inorganic catalysts, such as zinc, gold or zeolite, with traditional high energy chemical catalytic processes, our inexpensive process uses "renewable" biomolecules. They allow certain chemical reactions necessary to transform CO2 and water (H2O) into fuel molecules. Most of our process takes place at low temperature and low pressure, which requires much less energy than the other approaches.
The biocatalytic process (energy efficient) we operate occurs in some organisms where carbon atoms, extracted from CO2 and hydrogen extracted from water, are combined to create hydrocarbon molecules. Our revolutionary technology allows these processes to operate on an industrial scale very big lead thanks to nano-engineering of the biocatalysts and highly efficient
Now remains to see where they really are because the computer graphics that is fine but if this remains to 100% at the stage of ben theory then I too can say I photocatalysée runs on water !!