Monday , October 18 2021

Solving a 75-year-old mystery might be a new source of farm fertilizer


Titanium dioxide, also known as titania, has photocatalytic properties that allow it to react with nitrogen. Credit: Rob Felt, Georgia Tech

The solution to a 75-year-old material is a day that allows farmers to develop their nation's own fertilizer on demand, using sunlight and nitrogen from the air.

Thanks to a Special X-ray source at Lawrence Berkeley National Laboratory, researchers at the Georgia Institute of Technology have confirmed the existence of a long-hypothesized interaction between nitrogen and titanium dioxide (TiO2) – a common photoactive material also known as titania-in the presence of light. The catalytic reaction is believed to be used as carbon atom found in contaminants on the titania.

If the nitrogen-fixing reaction can be scaled up, it could be a day help power clean farm-scale fertilizer production that could reduce dependence on capital-intensive centralized production facilities and costly distribution systems that drive up costs for farmers in the isolated areas of the world . Most of the world's fertilizer is now made using ammonia produced by the Haber-Bosch process, which requires large amounts of natural gas.

"In the United States, we have a excellent production and distribution system for fertilizer." However, many countries are able to build Haber-Bosch plants, and may not even have sufficient transportation infrastructure to import fertilizers. For these regions, photocatalytic nitrogen fixation may be useful for on-demand fertilizer production, "said Marta Hatzell, a assistant professor in Georgia Tech's Woodruff School of Mechanical Engineering. "Ultimately, this could be a low-cost process that could make fertilizer-based nutrients available for a broader array of farmers."

Hatzell and collaborator Andrew Medford, an assistant professor in Georgia Tech's School of Chemical and Biomolecular Engineering, is working with scientists at the International Fertilizer Development Center (IFDC) to study the possible effects of the reaction process. The research was reported October 29 in the Journal of the American Chemical Society.

The research started more than two years ago When Hatzell and Medford began collaborating on a material mystery that originated with a 1941 paper published by Seshacharyulu Dhar, a Indian soil scientist who published compost from emoticon in the light of the day, Dhar suggested that a photocatalytic reaction with minerals be found in the ammonia.

Since that paper, other researchers have reported nitrogen fixation on titania and ammonia production, but the results have not been continuously experimental.

Georgia Tech graduate research assistant Yu-Hsuan Liu places a sample of titanium dioxide in test equipment in the laboratory of assistant professor Marta Hatzell. Credit: Rob Felt, Georgia Tech

Medford, a theoretician, worked with graduate research assistant Benjamin Comer to model the chemical pathways that would need to fix nitrogen on titania to potentially create ammonia using additional reactions. The calculations suggested the proposed process was highly unlikely on pure titania, and the researchers failed to win a grant. However, they were awarded experimental time on the Advanced Light Source at the U.S. Department of Energy's Lawrence Berkeley National Laboratory, which allowed them to finally test a key component of the hypothesis.

Specialized equipment at the lab allowed Hatzell and graduate student Yu-Hsuan Liu to use X-ray photoelectron spectroscopy (XPS) to examine the surface of titania as nitrogen, water and oxygen interacted with the surfaces under near-ambient pressure in the dark and in the light At first, the researchers saw no photochemical nitrogen fixation, but as the experiments continued, they observed a unique interaction between nitrogen and titania when light was directed at the minerals surface.

Georgia Tech graduate research assistant Yu-Hsuan Liu places a sample of titanium dioxide in test equipment in the laboratory of assistant professor Marta Hatzell. Credit: Rob Felt, Georgia Tech

What accounted for the results? Hatzell and Medford believe that surface contamination with carbon-potential from a hydrocarbon-is a necessary part of the catalytic process for nitrogen reduction on the titania. "Prior to testing, the samples are cleaned to remove all the trace carbon from the surface, but during experiments carbon from various sources (gases and the vacuum chamber) can be trace amount of carbon back on the sample," Hatzell explained. "What we observed was that the reduced nitrogen species only were detected if there was a degree of carbon on the sample."

The hydrocarbon contamination hypothesis would explain why earlier research had provided inconsistent results. Carbon is always present at trace levels on titania, but getting the right amount and type may be key to making the hypothesized reaction work.

"We think this explains the puzzling results that have been reported in the literature, and we hope it gives insights into how to engineer new catalysts using this 75-year-old mystery," Medford said. "Often the best catalysts are materials that are very pristine and made in a clean room. Here you have just opposite-this reaction really needs the impurities, which could be beneficial for sustainable applications in farming."

The researchers hopefully experimentally confirmed the role of carbon with the upcoming tests at Pacific Northwest National Laboratory (PNNL), which will allow them to directly probe the carbon during the photocatalytic nitrogen fixation process. They also want to learn more about the catalytic mechanism so that they are better than the one percent.

The research reported in the journal did not measure ammonia, but Hatzell and her students have found it in laboratory tests. Because the ammonia is currently produced at such low levels, the researchers had to take precautions to avoid ammonia-based contamination. "Even tape used on equipment can make small quantities of ammonia that can affect the measurements," Medford added.

Though the amounts of ammonia produced by the reaction is currently low, Hatzell and Medford believe that with improvements, the advantages of on-site fertilizer production under benign conditions can be overcome.

"While this may sound laughable from a practical perspective at first, if you're actually looking at the needs of the problem and the fact that sunlight and nitrogen from the air are free, on a cost basis it starts to look more interesting," Medford said . "If you could operate a small-scale ammonia production facility with enough capacity for one farm, you have made a difference."

Hatzell credits cutting-edge surface science is finally available an explanation to the mystery.

"Since earlier investigators looked at this, there were significant advances made in the area of ​​measurement and surface science," she said. "Most surface science measurements require the use of ultra-high vacuum conditions which do not mimic the catalytic environment you aim to investigate. The near ambient pressure XPS at Lawrence Berkeley National Lab, allowed us to take a step closer to this reaction in its native environment. "

Explore further:
Nitrogen fixation in ambient conditions

More information:
Benjamin M. Comer et al, The Role of Adventitious Carbon in Photo-catalytic Nitrogen Fixation by Titania, Journal of the American Chemical Society (2018). DOI: 10.1021 / jacs.8b08464

Journal reference:
Journal of the American Chemical Society

Provided by:
Georgia Institute of Technology

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