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Sunday, 1 October 2017

TU Delft Researcher Makes Alcohol Out Of Thin Air

Method of Producing Alcohol from Thin Air

Ming Ma, a TU Delft PhD student of Delft University of Technology, The Netherlands, haslocated a method of producing alcohol from thin air.. He has found out a way of efficiently and accurately controlling the process of electro-reduction of CO2 in producing a wide range of useful products comprising of alcohol.

 With the possibility of utilising CO2as a means of resource in this manner could be just essential in dealing with climate change. His PhD defence took place on September 14th. For the purpose of modifying atmospheric CO2 concentration, carbon capture together with utilization CCU can be a practicable alternative strategy to carbon capture and sequestrations –CCS.

The electrochemical reduction of CO2 to fuels together with value-added chemicals has drawn significant attention as a capable solution. In this course of development, the captured CO2 is utilised as a means of resource and transformed to carbon monoxide – CO, methane – CH4, ethylene and also liquid products like formic acid –HCOOH, methanol – CH3OH and ethanol C2 H5OH. The great energy density hydrocarbons tend to be utilised directly and conveniently as fuels in the existing energy infrastructure.

Feedstock in Fischer-Tropsch

Besides the production of CO2 seems to be interesting as it could be utilised as feedstock in the process of Fischer-Tropsch, which is a strong technology used extensively in industry in the conversion of syngas CO and hydrogen H2 into useful chemicals like methanol and synthetic fuels like diesel fuel.

Ming Ma, in his PhD theory, while working in the group of Dr Wilson A. Smith had defined that the processes that seemed to occur at the nanoscale when various metals were utilised in the electro-reduction of CO2. For instance, while utilising copper nanowires in the electro-reduction procedure would lead to production of hydrocarbons though nanoporous silver could develop CO.

Moreover, as per the discovery of Ma, the process could be quite accurately regulated by altering the lengths of the nanowires as well as the potential of the electrical. On modifying these conditions one is capable of generating any carbon based production or alternatively combinations in any desired ratio, thereby producing the resources for the three follow up processes mentioned above. On utilising metal alloys in the procedure, would lead to more stimulating results.

Formic Acid – Favourable usage in Fuel Cells

Though platinum tends to produce hydrogen on its own, and gold tends to generate CO, an alloy of these two metals tend to unexpectedly produce formic acid – HCOOH, in relatedly huge quantities where formic acid is said to have the possibilities of a very favourable usage in fuel cells. After this, the next step for the team at the Smith Lab for solar Energy Conversion and Storage at TU Delft is to look for means of enhancing the selectivity of individual products as well to start the designing of scaling up the procedure.

Smith had received an ERC Starting Grant to work on that to improve the understanding of the complicated reaction mechanism to obtain an improved control of the CO2electro catalytic process. The other task in the lab is directed on solar driven splitting of water wherein the simple solution tends to make hydrogen production from solar water splitting more efficient and cheaper. With cheap efficient and stable photo electrode would help in improving water splitting with solar energy.

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