New Way to 'Fix' Nitrogen Discovered

A scientific article describing the method, which uses a simple compound of iron and hydrogen as the electron source in the "fixing" reaction, will be published in the July 27 issue of the Journal of the American Chemical Society.

The process devised by University of Oregon chemistry professor David Tyler and two graduate students, John Gilbertson and Nate Szymczak, was carried out in ether solutions. However, all steps but one also have been shown to work in water.

In the atmosphere, nitrogen gas is inert. However when nitrogen is converted to ammonia, it becomes available as a nitrogen source for plant growth - and as such is the fertilizer that drives the world's food supply. Industry produces ammonia using the century-old Haber-Bosch process, which directly combines nitrogen from the air with hydrogen under extremely high pressures and temperatures.

"For the first time, we've been able to use hydrogen as the source of electrons in the laboratory fixation of nitrogen," Tyler said. "Until now people have had to use other sources of electrons that are not relevant to the Haber-Bosch process. The only other case in which hydrogen was used successfully required higher temperature and exotic materials."

"In the eyes of chemists, the conversion of nitrogen to ammonia in water, using simple hydrogen at room temperature and pressure is the holy grail of nitrogen fixation," Tyler said. "The next challenge is figuring out how to carry out the complete cycle in water."

The University of Oregon method parallels the Haber-Bosch process very closely by using the electrons in the hydrogen molecule as the source of electrons required in the fixing reaction. "This is simpler than any other solution put forward to date," Tyler said. "Other procedures involve the use of relatively exotic electron sources or they require elevated temperatures to complete the synthesis."

And, while the new method "provides one solution to a fascinating, fundamental scientific challenge," Tyler emphasized that it could be decades - if ever - before it will bridge from the bench to cost-effective industry use.

Tyler said the new approach to synthesizing ammonia took five years to achieve and was inspired by earlier advances made by his graduate students, who found ways to make complexes soluble in water. He pointed out that Gilbertson and Szymczak both are funded by the university's National Science Foundation grant establishing research positions in Materials Science through the IGERT (Integrative Graduate Education and Research Traineeship) program.

"Solving problems of this magnitude takes a lot of student power and research dollars," Tyler said. "We're building on advances achieved during the last 20 years. A lot of hard thought went into this, not only by me and my students, but by other researchers who came before us."

Students chosen for the IGERT program receive opportunities to pursue interdisciplinary research, teach at other campuses, and do internships at National Labs and private companies. Gilbertson, who will complete his doctorate in chemistry in August, will begin a teaching postdoctoral position at Trinity University in San Antonio, Texas this fall. Szymczak currently has an internship at Pacific Northwest National Laboratories.

Source: University of Oregon

At 2.8 km down, a 1-of-a-kind microorganism lives all alone
The first ecosystem ever found having only a single biological species has been discovered 2.8 kilometers (1.74 miles) beneath the surface of the earth in the Mponeng gold mine near Johannesburg, South Africa. There the rod-shaped bacterium Desulforudis audaxviator exists in complete isolation, total darkness, a lack of oxygen, and 60-degree-Celsius heat (140 degrees Fahrenheit).
Benchmark cyanobacterium sequenced could be cheap renewable energy source
(PhysOrg.com) -- A team of researchers headed by biologists at Washington University in St. Louis has sequenced the genome of a unique bacterium that manages two disparate operations — photosynthesis and nitrogen fixation — in one little cell during two distinct cycles daily.
Photosynthesizing bacteria with a day-night cycle contain rare chromosome
Researchers sequencing the DNA of blue-green algae found a linear chromosome harboring genes important for producing biofuels. Simultaneously analyzing the complement of proteins revealed more genes on the linear and the typical circular chromosomes then they'd have found with DNA sequencing alone.
Putting the Squeeze on Nitrogen for High Energy Materials
(PhysOrg.com) -- Nitrogen atoms like to travel in pairs, hooked together by one of the strongest chemical bonds in nature. By subjecting nitrogen molecules to extreme temperatures and pressures scientists are getting a new understanding of not only nitrogen but other similar molecules, including hydrogen. In the current online edition of Physical Review Letters, researchers from the Carnegie Institution's Geophysical Laboratory report changes in the melting temperature of solid nitrogen at pressures up to 120 gigapascals (more than a million atmospheres) and temperatures reaching 2,500° Kelvin (more than 4000° Fahrenheit).
Green catalysts provide promise for cleaning toxins and pollutants
Tetra-Amido Macrocyclic Ligands (TAMLs) are environmentally friendly catalysts with a host of applications for reducing and cleaning up pollutants, and a prime example of "green chemistry." Carnegie Mellon University's Terry Collins, the catalyst's inventor, believes that the small-molecule catalysts have the potential to be even more effective than previously proven.
Now That's Cool: Engineers Out to Thaw the Mysteries of Ice
(PhysOrg.com) -- "Ye canna change the laws of physics!" Scotty warned Captain Kirk on Star Trek. But engineers and physicists at the University of Maryland may rewrite one of them.
Scientists a step closer to producing fuel from bacteria
Scientists at the University of Sheffield have shown how bacteria could be used as a future fuel. The research, published in the journal Bioinformatics, could have significant implications for the environment and the way we produce sustainable fuels in the future.
Chemists use 'green chemistry' to produce amines, chemical compounds used widely in industry
Chemists at UC Riverside have discovered an inexpensive, clean and quick way to prepare amines – nitrogen-containing organic compounds derived from ammonia that have wide industrial applications such as solvents, additives, anti-foam agents, corrosion inhibitors, detergents, dyes and bactericides.

New Way to 'Fix' Nitrogen Discovered

Related stories:

News discussion: