(Top) Transmission electron microscope images show the change in color as silver (in blue) leaches out of a nanoparticle over several hours, leaving gold atoms behind. (Bottom) Hyperspectral images show how much a nanoparticle of silver and gold shrank over four hours as the silver leached away. Image: Rice University.Gold-silver alloys are useful catalysts for degrading environmental pollutants, facilitating the production of plastics and chemicals, and killing bacteria on surfaces, among other applications. In nanoparticle form, these alloys could be useful as optical sensors or to catalyze hydrogen evolution reactions. But there's an issue: the silver doesn't always stay put.
Now, a new study by scientists at Rice University and the University of Duisburg-Essen in Germany reveals a two-step mechanism behind silver's dissipation, a discovery that could help industry fine-tune nanoparticle alloys for specific uses.
The scientists, led by Rice chemists Christy Landes and Stephan Link and graduate student Alexander Al-Zubeidi and Duisburg-Essen chemist Stephan Barcikowski, employed sophisticated microscopy to reveal how gold might retain enough silver to stabilize the nanoparticle. They report their findings in a paper in ACS Nano.
The scientists used a hyperspectral dark-field imaging microscope to study gold-silver alloy nanoparticles containing an excess of silver in an acidic solution. This technique allowed them to trigger plasmons, ripples of energy that flow across the surface of metal particles when illuminated. These plasmons scatter light at wavelengths that change with the alloy's composition.
"The dependence of the plasmon on alloy composition allowed us to record silver ion leaching kinetics in real time," explained Al-Zubeidi, lead author of the paper.
Gold and silver alloys have been in use for decades, often as antibacterial coatings, because silver ions are toxic to bacteria. "I think the silver release mechanism has been implied from studies of alloy films, but it's never been proven in a quantitative way," Al-Zubeidi said.
The study revealed that silver ions initially leach quickly from nanoparticles, which literally shrink as a result. As the process continues, the gold lattice in most instances releases all the silver over time, but about 25% of particles behave differently, leading to incomplete silver leaching.
According to Al-Zubeidi, what they observed suggests gold could be manipulated to stabilize the alloy nanoparticles.
"Usually, silver leaching would last about two hours under our conditions," he said. "Then in the second stage, the reaction no longer happens on the surface. Instead, as the gold lattice rearranges, the silver ions have to diffuse through this gold-rich lattice to reach the surface, where they can be oxidized. That slows the reaction rate a lot.
"At some point, the particles passivate and no more leaching can happen. The particles become stable. So far, we've only looked at particles with a silver content of 80–90%, and we found that a lot of the particles stop leaching silver when they reach a silver content of about 50%.
"That could be an interesting composition for applications like catalysis and electrocatalysis. We'd like to find a sweet spot around 50%, where the particles are stable but still have a lot of their silver-like properties."
Understanding such reactions could help researchers build a library of gold-silver catalysts and electrocatalysts for various applications.
Link said the Rice team welcomed the opportunity to work with Barcikowski, a leader in the field of nanoparticle synthesis via laser ablation: "This makes it possible to create alloy nanoparticles with various compositions and free of stabilizing ligands."
"From our end, we had the perfect technique to study the process of silver ion leaching from many single-alloy nanoparticles in parallel via hyperspectral imaging," Landes added. "Only a single-particle approach was able to resolve the intra- and interparticle geometry."
"This effort will enable a new approach to generate nanostructured catalysts and new materials with unique electrochemical, optical and electronic properties," said Robert Mantz, program manager for electrochemistry at the Army Research Office, an element of the US Army Combat Capabilities Command's Army Research Laboratory. "The ability to tailor catalysts is important to achieve the goal of reducing soldier-borne weight associated with power storage and generation, and enable novel material synthesis."
This story is adapted from material from Rice University, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.