UB Chemist to Receive Solid-State Award from American Chemical Society

Release Date: May 12, 2010 This content is archived.

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Chemist Sarbajit Banerjee will be honored by the American Chemical Society in August for his research into the next generation of transistors.

BUFFALO, N.Y. -- A chemist at the University at Buffalo has been recognized by the American Chemical Society for his research of a material that could be used for the next generation of transistors.

Sarbajit Banerjee, PhD, assistant professor of chemistry, will be awarded the ExxonMobil Solid-State Chemistry Award at the American Chemical Society Fall meeting in August. The award will be presented by the ACS Division of Inorganic Chemistry.

The award is given "to recognize significant contributions in solid-state chemistry by junior faculty at U.S. institutions and support solid-state chemistry as a recognized discipline," according to the ACS website. Banerjee is the sole recipient this year.

"It's definitely an honor to be recognized so early in my career," Banerjee said, acknowledging that the accolade rewards everyone involved in his project, especially graduate and undergraduate students. "It's essentially recognition from the community that what we do is important."

Banerjee received his undergraduate education at the University of Delhi and his doctorate at Stony Brook University. Before coming to teach at UB, Banerjee was a postdoctoral research scientist at Columbia University.

Banerjee's research included the study of vanadium oxide, currently used in night-vision technologies. Vanadium oxide is a unique substance that switches between metallic and non-metallic phases at a specific temperature, usually about 160 degrees Fahrenheit. By reducing vanadium oxide to a nanomaterial, and by doping the material with tungsten, Banerjee and his team have reduced the tipping point to a minimum of around -4 degrees Fahrenheit.

"When we look at crystal structures, what we find is that when you make them small, like a nanoparticle, the arrangement of atoms can change," said Banerjee. "We can get all these cool materials that don't normally exist at room temperature. We have a lot of control over how we stabilize them, too."

Another benefit of using these oxides as nanomaterials, according to Banerjee, is that they act more predictably in smaller pieces.

"You can uncover new phenomena that are obscured in larger materials," he said. "You can uncover its intrinsic properties because there aren't as many defects in it."

The research could lead to a new generation of smart materials that could be used in windows, for example, for thermally specific heat conductivity. Banerjee also notes that the material could potentially be used for "high-mobility switching elements, and the next generation of transistors."

Banerjee is interested in how different disciplines can collaborate to find chemical solutions to human problems.

"Science is becoming more interdisciplinary as time goes by," says Banerjee. "It's actually part of what UB 2020 is all about. A lot of challenges are at the intersection of different disciplines."

In his classes, Banerjee says, he often has students studying engineering, as well as those who pursue the natural sciences. For him, the examination and manipulation of the chemical world has merit for everyone in it, not just those vested in academic interests. Chemistry, he says, is a point of view, which unlocks the secret structures within the objects humans take for granted.

"Solid state chemistry really is the way I see the world," Banerjee said.

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