MIT researchers develop oxygen permeable membrane that converts CO2 to CO
28 November 2017
MIT researchers have developed a new system that could potentially be used for converting power plant emissions of carbon dioxide into carbon monoxide, and thence into useful fuels for cars, trucks, and planes, as well as into chemical feedstocks for a wide variety of products.
The new membrane-based system for CO2 thermochemical reduction was developed by MIT postdoc Xiao-Yu Wu and Ahmed Ghoniem, the Ronald C. Crane Professor of Mechanical Engineering, and is described in a paper in the journal ChemSusChem. The membrane, made of a compound of lanthanum, calcium, and iron oxide, allows oxygen from a stream of carbon dioxide to migrate through to the other side, leaving carbon monoxide behind. Other compounds, known as mixed ionic electronic conductors, are also under consideration in their lab for use in multiple applications including oxygen and hydrogen production.
Carbon monoxide produced during this process can be used as a fuel by itself or combined with hydrogen and/or water to make many other liquid hydrocarbon fuels as well as chemicals including methanol (used as an automotive fuel), syngas, and so on. Ghoniem’s lab is exploring some of these options.
The membrane, with a structure known as perovskite, is 100% selective for oxygen, allowing only those atoms to pass, Wu explains. The separation is driven by temperatures of up to 990 degrees Celsius, and the key to making the process work is to keep the oxygen that separates from carbon dioxide flowing through the membrane until it reaches the other side. This could be done by creating a vacuum on side of the membrane opposite the carbon dioxide stream, but that would require a lot of energy to maintain.
In place of a vacuum, the researchers use a stream of fuel such as hydrogen or methane. These materials are so readily oxidized that they will actually draw the oxygen atoms through the membrane without requiring a pressure difference. The membrane also prevents the oxygen from migrating back and recombining with the carbon monoxide, to form carbon dioxide all over again. Ultimately, and depending on the application, a combination of some vacuum and some fuel can be used to reduce the energy required to drive the process and produce a useful product.
The energy input needed to keep the process going, Wu says, is heat, which could be provided by solar energy or by waste heat, some of which could come from the power plant itself and some from other sources. Essentially, the process makes it possible to store that heat in chemical form, for use whenever it’s needed.
At this point, Wu says, he and Ghoniem have demonstrated that the process works. Ongoing research is examining how to increase the oxygen flow rates across the membrane, perhaps by changing the material used to build the membrane, changing the geometry of the surfaces, or adding catalyst materials on the surfaces. The researchers are also working on integrating the membrane into working reactors and coupling the reactor with the fuel production system. They are examining how this method could be scaled up and how it compares to other approaches to capturing and converting carbon dioxide emissions, in terms of both costs and effects on overall power plant operations.
In a natural gas power plant that Ghoniem’s group and others have worked on previously, Wu says the incoming natural gas could be split into two streams, one that would be burned to generate electricity while producing a pure stream of carbon dioxide, while the other stream would go to the fuel side of the new membrane system, providing the oxygen-reacting fuel source. That stream would produce a second output from the plant: syngas. Syngas is a widely used industrial fuel and feedstock. The syngas can also be added to the existing natural gas distribution network.
The process can work with any level of carbon dioxide concentration, Wu says—they have tested it all the way from 2 to 99 percent—but the higher the concentration, the more efficient the process is. So, it is well-suited to the concentrated output stream from conventional fossil-fuel-burning power plants or those designed for carbon capture such as oxy-combustion plants.
The research was funded by Shell Oil and the King Abdullah University of Science and Technology.
Resources
Wu, X.-Y. and Ghoniem, A. F. (2017), H2-assisted CO2 thermochemical reduction on La0.9Ca0.1FeO3-δ membranes: a kinetics study. ChemSusChem. Accepted Author Manuscript. doi:10.1002/cssc.201701372
This could lead to better ways to separate various elements from Gases and Liquids. Could also lead to future lower cost H2 for industrial and commercial uses.
The separated elements could be stored and use for clean e-energy generation.
Posted by: HarveyD | 30 November 2017 at 07:59 AM
It takes most of the energy you get from burning carbon to CO2 to convert CO2 back to CO.
This is of questionable use except to make syngas. It doesn't even take the nitrogen out of your CO2/CO stream. Having to use a fuel to recombine the oxygen on the other side of the perovskite membrane suggests that it cannot endure highly oxidizing conditions, so it can't just pump oxygen ions using electric power (which would also have to be sourced from some non-emitting source... at the same time fuel was being burned to make the CO2. Why?).
I take that back. This is insane.
Posted by: Engineer-Poet | 30 November 2017 at 03:55 PM