The Science
The Impact
Ruthenium nanoparticles have the potential to be an important catalyst for producing hydrogen fuel. (Nanoparticles are particles that are less than 100 nanometers, which is about one-thousandth the width of a human hair.) However, most of the time, the ruthenium dissolves in the first few cycles. This work shows that it is possible for scientists to control the ruthenium’s crystal structure. This could allow them to improve how well ruthenium performs in hydrogen fuel cells. In addition, researchers can apply these principles to a range of different metal nanoparticles. That information will help them create nanocatalysts with high levels of activity and stability.
Summary
It is vital to understand how the crystallinity and surface facets of branched nanoparticles affect catalysts’ performance. One context for such performance is splitting water for hydrogen fuel production. This process involves an anodic reaction (where electrons flow from the fuel cell’s anode) called the oxygen evolution reaction. Ruthenium nanoparticles are the most active catalyst for this reaction. However, their use is limited because typically the ruthenium will completely dissolve in the first few reaction cycles. There is some evidence that scientists could reduce the dissolution by using ruthenium metal surfaces with low energy crystal faces. Such nanoparticles are both stable and active, and they are a key target for oxygen evolution reaction catalysts. This team has made an important advance toward this target by synthesizing and characterizing branched ruthenium nanoparticles with precise control over crystallinity. The team designed the nanoparticles with two critical features: a high surface area, which increases catalytic activity, and low-energy crystal surfaces, which greatly increases catalytic stability. They found that, by using low ratios of the organic molecules that are used to direct the growth of the nanoparticles, they were able to achieve their goal of long, highly crystalline branches with low energy surfaces. The nanoparticles had much better stability and a five-fold increase in reaction activity compared to polycrystalline ruthenium nanoparticles. This work highlights the importance of synthetically controlling nanoparticle crystallinity to optimize surface properties for electrocatalysis.
Funding
A.R.P. is supported by an Australian Government Research Training Program Scholarship and the UNSW Scientia PhD Scholarship Scheme. L.G., J.J.G., and R.D.T acknowledge funding under the Australian Research Council Linkage grant. Support from the Australian Research Council through the award of an Australian Laureate Fellowship for J.J.G and a Discovery Project for R.D.T. are acknowledged. This research used the facilities supported by Microscopy Australia (formerly AMMRF) at the Electron Microscope Unit at UNSW. This work was performed, in part, at the Center for Integrated Nanotechnologies (CINT), an Office of Science User Facility operated for the U.S. Department of Energy (DOE), Office of Science.
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