From DOE’s SLAC National Accelerator Laboratory: “Study shows tweaking one layer of atoms on a catalyst’s surface can make it work better”

From DOE’s SLAC National Accelerator Laboratory

January 11, 2021 [Just now in social media.]
Glennda Chui

The surprising results offer a way to boost the activity and stability of catalysts for making hydrogen fuel from water.

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Credit: SLAC.

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An illustration combines two possible types of surface layers for a catalyst that performs the water-splitting reaction, the first step in making hydrogen fuel. The gray surface, top, is lanthanum oxide. The colorful surface is nickel oxide; a rearrangement of its atoms while carrying out the reaction made it twice as efficient, a phenomenon researchers hope to harness to design better catalysts. Lanthanum atoms are depicted in green, nickel in blue and oxygen in red. Credit: CUBE3D Graphic.

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A new study shows how tweaking the surface layer of a catalyst can make it work better. This particular catalyst is used to split water, the first step in making hydrogen fuel. It consists of alternating layers of materials rich in nickel (blue spheres) and lanthanum (green spheres; the red spheres represent oxygen atoms). When the material is grown at relatively cool temperatures so a nickel-rich layer is on top (left), the atoms on that surface layer rearrange during the water-splitting reaction (middle) in a way that allows them to carry out the reaction more efficiently (right). This surprising result gives scientists a new way to tune catalytic activity and engineer better catalysts. Credit:Tomas Duchon/Jülich Research Centre [Forschungszentrum Jülichs] (FZJ)(DE)[DE]).

Scientists crafting a nickel-based catalyst used in making hydrogen fuel built it one atomic layer at a time to gain full control over its chemical properties. But the finished material didn’t behave as they expected: As one version of the catalyst went about its work, the top-most layer of atoms rearranged to form a new pattern, as if the square tiles that cover a floor had suddenly changed to hexagons.

But that’s ok, they reported today, because understanding and controlling this surprising transformation gives them a new way to turn catalytic activity on and off and make good catalysts even better.

The research team, led by scientists from Stanford University and the Department of Energy’s SLAC National Accelerator Laboratory, described their study in Nature Materials today.

“Catalysts can change very quickly during the course of a reaction, and understanding how they transform from an inactive phase to an active one is crucial to designing more efficient catalysts,” said Will Chueh, an investigator with the Stanford Institute for Materials and Energy Sciences (SIMES) at SLAC who led the study. “This transformation gives us the equivalent of a knob we can turn to fine-tune their behavior.”

Splitting water to make hydrogen fuel

Catalysts help molecules react without being consumed in the reaction, so they can be used over and over. They’re the backbone of many green-energy devices.

This particular catalyst, lanthanum nickel oxide or LNO, is used to split water into hydrogen and oxygen in a reaction powered by electricity. It’s the first step in generating hydrogen fuel, which has enormous potential for storing renewable energy from sunlight and other sources in a liquid form that’s energy-rich and easy to transport. In fact, several manufacturers have already produced electric cars powered by hydrogen fuel cells.

But this first step is also the most difficult one, said Michal Bajdich, a theorist at the SUNCAT Center for Interface Science and Catalysis at SLAC, and researchers have been searching for inexpensive materials that will carry it out more efficiently.

Since reactions take place on a catalyst’s surface, researchers have been trying to precisely engineer those surfaces so they promote only one specific chemical reaction with high efficiency.

Building materials one atomic layer at a time

The LNO investigated in this study belongs to a class of promising catalytic materials known as perovskites, named after a natural mineral with a similar atomic structure.

Christoph Baeumer, who came to SLAC as a Marie Curie Fellow from RWTH Aachen University [Rheinisch-Westfälische Technische Hochschule Aachen] (DE) to carry out the study, prepared LNO in what’s known as an epitaxial thin film – a film grown in atomically thin layers in a way that creates an extraordinarily precise arrangement of atoms.

Dividing his time between California and Germany, Baeumer made two versions of the film at different temperatures ­­– one with a nickel-rich surface and another with a lanthanum-rich surface. Then the research team ran all the versions through the water-splitting reaction to compare how well they performed.

“We were surprised to discover that the films with nickel-rich surfaces carried out the reaction twice as fast,” Baeumer said.

Tuning a catalyst’s surface for better performance

To find out why, the team took the films to DOE’s Lawrence Berkeley National Laboratory, where a group led by Slavomír Nemšák looked at their atomic structure with X-rays at the Advanced Light Source.

LBNL ALS .

“It was surprising that the difference between the ‘good’ and the ‘bad’ catalyst was only in the last atomic layer of the films,” Nemšák said. Those investigations also revealed that in films with nickel-rich surface layers that were prepared at cooler temperatures, the top layer of atoms transformed at some point during the water-splitting reaction, and this new arrangement boosted the catalytic activity.

Meanwhile, Jiang Li, a postdoctoral researcher and theorist at SUNCAT, performed computational studies of this very complex system using Berkeley Lab’s National Energy Research Scientific Computing Center (NERSC).

National Energy Research Scientific Computing Center (NERSC) at Lawrence Berkeley National Laboratory

NERSC Cray Cori II supercomputer, named after Gerty Cori, the first American woman to win a Nobel Prize in science.

NERSC Hopper Cray XE6 supercomputer, named after Grace Hopper, One of the first programmers of the Harvard Mark I computer.

NERSC Cray XC30 Edison supercomputer.

NERSC GPFS for Life Sciences.


The Genepool system is a cluster dedicated to the DOE Joint Genome Institute’s computing needs. Denovo is a smaller test system for Genepool that is primarily used by NERSC staff to test new system configurations and software.

NERSC PDSF computer cluster in 2003.

PDSF is a networked distributed computing cluster designed primarily to meet the detector simulation and data analysis requirements of physics, astrophysics and nuclear science collaborations.

Future:

Cray Shasta Perlmutter SC18 AMD Epyc Nvidia pre-exascale supeercomputer

NERSC is a DOE Office of Science User Facility.

His conclusions agreed with the experimental results, predicting that the version of the catalyst with the transformed surface – from a cubic pattern to a hexagonal one – would be the most active and stable one.

Bajdich said, “Is the transformation of the nickel-rich surface driven by the way the catalyst is prepared, or by changes it undergoes while it carries out the water-splitting reaction? That’s very hard to answer. It looks like both have to occur.”

Although this particular catalyst is not the best in the world for splitting water into hydrogen and oxygen, he said, discovering how a surface transformation boosts its activity is important and could potentially apply to other materials too.

“If we can unlock the secrets of this transformation so we can accurately tune it,” he said, “then we can leverage this phenomenon to make much better catalysts in the future.”

See the full article here .


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SLAC is a multi-program laboratory exploring frontier questions in photon science, astrophysics, particle physics and accelerator research. Located in Menlo Park, California, SLAC is operated by Stanford University for the DOE’s Office of Science.

SLAC National Accelerator Lab


SLAC/LCLS


SLAC/LCLS II projected view

SLAC LCLS-II Undulators The Linac Coherent Light Source’s new undulators each use an intricately tuned series of magnets to convert electron energy into intense bursts of X-rays. The “soft” X-ray undulator stretches for 100 meters on the left side of this hall, with the “hard” x-ray undulator on the right. Credit: Alberto Gamazo/SLAC National Accelerator Laboratory.

SSRL and LCLS are DOE Office of Science user facilities.