Process turns wheat flour into CO2-capturing micropores

micropores
Purdue doctoral student Arthur Dysart operates a system that measures the adsorption of gas molecules on a solid carbon surface. He is working on a team developing materials that capture carbon dioxide, a strategy aimed at reducing the effects of climate change. (Purdue University image/John Underwood)

 

micropores
Vilas Pol, an associate professor in the School of Chemical Engineering and the School of Materials Engineering, is working to perfect a process that turns wheat flour into numerous tiny pores that capture carbon dioxide, representing a potential renewable technology to reduce the industrial emission of carbon dioxide into the atmosphere. (Purdue University image/John Underwood)

Researchers have shown how a process for the “carbonization” of wheat flour creates numerous tiny pores that capture carbon dioxide, representing a potential renewable technology to reduce the industrial emission of carbon dioxide into the atmosphere.

“With increasing carbon dioxide emissions, global warming is accelerating, accompanied by abnormal climate changes,” said Vilas Pol, an associate professor in Purdue University‘s School of Chemical Engineering and the School of Materials Engineering. “It is imperative to develop efficient methods for capturing carbon dioxide.”

Purdue researchers developed a process that creates carbon compartments from wheat flour. Collaborating with researchers at Korea University in Seoul, South Korea, they studied carbon dioxide capture in these unique carbon compartments. The chemical compound potassium hydroxide was used to “activate” – or generate many small pores – in the wheat flour inside a furnace at 700 degrees Celsius.

The carbon dioxide is “adsorbed,” or bound to the material‘s surface inside the micropores.

“The outstanding overall carbon dioxide adsorption performance indicates that potassium hydroxide-activated microporous carbon compartments can be a promising approach,” said associate professor Ki Bong Lee from Korea University.

The researchers varied the ratio of potassium hydroxide to carbon until finding a formulation that performed the best.

Findings are detailed in a research paper appearing on Tuesday (Oct. 4) in the journal scientific-reports/” title=”View all articles about Scientific Reports here”>Scientific Reports. The paper was authored by researchers Seok-Min Hong and Eunji Jang, graduate students from Korea University; Purdue chemical engineering doctoral student Arthur D. Dysart; Pol; and Lee.

Findings showed the rate of carbon dioxide adsorption depends on the material‘s volume of micropores with a pore size less than .8 nanometers. The researchers also demonstrated that the material can be rapidly used over again to repeatedly capture carbon dioxide.

Future research will include work to adsorb larger quantities of carbon dioxide.

The research was supported by the National Research Foundation, the Basic Science Research Program and the Human Resources Development Program of the Korea Institute of Energy Technology Evaluation and Planning. Purdue University’s carbon compartment development process was supported by the U.S. Department of Energy.