Quantum gold

September 2013
Filed under: Brookhaven
Driven by what’s missing in experiments, Brookhaven's Yan Li applies quantum mechanics to compute the physical properties of materials.
A model of a nanocluster comprised of 11 gold atoms with attached ligand atoms. (Yan Li, Brookhaven National Laboratory.)

A model of a nanocluster comprised of 11 gold atoms with attached ligand atoms. (Yan Li, Brookhaven National Laboratory.)

A summer doing lab experiments as a doctoral student was enough for Yan Li. “I figured out I may be too clumsy to be a lab scientist” and eventually turned to computers, she says.

Li now is an assistant computational scientist at Brookhaven National Laboratory on New York’s Long Island, but that doesn’t mean she’s completely forsaken the lab bench. She often collaborates with experimental groups – partnerships that, among other things, study ways to make solar energy cheaper, more efficient and more flexible, whether to produce electricity or clean-burning hydrogen.

Most of Li’s work is motivated by what’s missing in experiments. “There are answers (scientists) can’t figure out simply by using experimental techniques or there are things they want to make predictions about before they try a new experiment. These are the areas theory, modeling and computation can help.”

Li focuses on first-principles electronic structure theory calculations: applying fundamental rules from the strange world of quantum mechanics while forsaking any adjustable parameters to compute the physical properties of materials, whether as molecules, surfaces, crystals or nanometer-sized structures.

The calculations are especially demanding because they adhere to quantum mechanical principles, which exact a higher computational cost than classical physics models. With first-principle electronic structure theory, Li and her colleagues decipher the detailed properties of materials at the atomic scale what happens at the interfaces where they meet.

Their favorite method: density functional theory (DFT), a generally accurate and reliable approach that takes much less computer time to reach a solution than quantum chemistry techniques. Its balance of accuracy and affordability makes DFT the most popular computational method for research in chemistry, materials science and other disciplines, Li says.

But “depending on the particular property you’re interested in, we have to go beyond DFT or combine” it with another method. That’s the case in one recent project to help solve a mystery involving gold nanoparticles, sunlight and hydrogen production.

Stony Brook University doctoral candidates Peichuan Shen and Shen Zao, with Alexander Orlov, materials science and engineering professor, study cadmium sulfide, a material that, when exposed to sunlight, mildly acts as a catalyst to produce hydrogen from water.

“It’s a standard substrate, not really fancy, but it has some unimpressive photocatalytic activity,” Li says. When the Stony Brook researchers seeded the cadmium sulfate with nanoparticles of different sizes and composition, they found gold clusters boosted hydrogen production by as much as 35 times.

The gold particles that worked best were about a nanometer in size – each just tens of atoms, as Brookhaven staff scientist Dong Su showed with high-tech transmission electron and scanning transmission electron microscopes. The researchers weren’t sure, however, what precise particle size contributed most to the enhanced effect or how they work. They could only average results from all the sizes on the substrate.

The Stony Brook researchers “have been scratching their heads trying to figure out what the mechanism is. … They were happy that it worked, and it works great, but they hadn’t figured out why and how. That’s where we came in.”

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