University of Illinois postdoctoral researcher Juyeong Kim (left), graduate student Zihao Ou (middle) and professor Qian Chen (right) have developed a new technique for observing colloidal nanoparticles while they interact and self-assemble. Photo by L. Brian Stauffer.Seeing is believing when it comes to nanoparticle self-assembly. A team of engineers at the University of Illinois at Urbana-Champaign is observing the interactions of colloidal gold nanoparticles inside tiny aquarium-like sample containers with the aim of gaining more control over the self-assembly process of engineered materials.
Self-assembling colloidal nanoparticles are one of the things that make devices like LED displays, solar cells and batteries work. Conventionally, researchers have studied these nanoparticles using still images produced by high-powered electron microscopes. But because colloidal nanoparticles interact through motions in liquids, traditional electron microscopy-based observation methods cannot capture the interactions that occur when these nanoparticles self-assemble, explained Qian Chen, a professor of materials science and engineering and co-author of a paper on the study in Nature Communications.
"The colloid self-assembly process has always been a bit of a black box," Chen said. "The particles behave like atoms and molecules, which allows us to use classical chemistry and physics theories to model their behavior. This new method, called liquid-phase transmission electron microscopy (TEM), allows us to see exactly what is happening." The team's new method also shows that the shape of the nanoparticles can control the types of materials formed.
"One challenge in nanotechnology is conquering our inability to control the process of artificial assembly," Chen said. "By working with particles of different shapes, we can control how the particles stack up together, almost like playing with tiny Legos toys. This type of control will make a difference in a material's properties and application."
"We can follow the trajectory of the nanoparticles, precisely and continuously, which gives us the power to map out the assembly rate laws quantitatively," said postdoctoral researcher and lead author Juyeong Kim. "Particular shapes prefer to attach in a way similar to how molecules connect into big polymers, and we can reproduce those conditions, which is a huge step forward in the fundamental understanding and the control over nanoparticle self-assembly."
The group chose to conduct their experiments with colloidal gold nanoparticles for several reasons. "Gold shows excellent contrast under TEM because it is a heavy element, making it easy to observe," said graduate student and co-author Zihao Ou. "It is also a very stable and generally nontoxic element, which is beneficial for applications within the human body, like medicine."
"Colloidal gold contains a property that allows it to concentrate electromagnetic radiation, like light waves, allowing it to generate heat," said Kim. "One possible application of this is something called photothermal therapy, where we can inject colloidal gold into a patient to target cancer cells and destroy them with heat."
Chen also envisions the liquid-phase TEM method being used to study the structure of proteins and microorganisms within the human body. Proteins generally need to be frozen or crystallized for analysis, which is not ideal. Her group is now looking at proteins in liquid environments using liquid-phase TEM to see how they self-assemble and change their shape.
This story is adapted from material from the University of Illinois at Urbana-Champaign, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.