Led by Northwestern University and the University of Illinois, Urbana-Champaign, the research team says these new insights could be used to design new materials, including thin films for electronic applications.
The research was published today (March 30) in the journal Nature Nanotechnology.
Described by the researchers as an “experimental tour de force,” the study used a newly optimized form of liquid-phase transmission electron microscopy (TEM) to gain unprecedented insights into the self-assembly process. Before this work, researchers used microscopy to watch micron-sized colloids — which are 10 to 100 times larger than nanoparticles — self-assemble into crystals. They also have used X-ray crystallography or electron microscopy to visualize single layers of atoms in a crystalline lattice. But they were unable to watch atoms individually move into place.
“We know that atoms use a similar scheme to assemble into crystals, but we have never seen the actual growth process,” said Northwestern’s Erik Luijten, who led the theoretical and computational work to explain the observations. “Now we see it coming together right in front of our eyes. By viewing nanoparticles, we are watching particles that are larger than atoms, but smaller than colloids. So, we have completed the whole spectrum of length scales. We are filling in the missing length.”
"Previously, our team resolved the mystery of nucleation, namely how the embryos of crystals composed of tens of nanoparticles are formed, which follows a nonclassical pathway in solution,” said Illinois’ Qian Chen, who led the experimental work. “With recent advances in liquid-phase TEM and data science, in this work, we are now able to capture and track motions of thousands of nanoparticles over time. These nanoparticles wiggle in solution and grow into crystals of various morphologies like polyhedral or wedding cake.”
Luijten is a professor of materials science and engineering at Northwestern’s McCormick School of Engineering, where he also is an associate dean. Chen is an associate professor of materials science and engineering at Illinois.
Most people are familiar with crystals in the forms of salt, sugar, snowflakes and sparkling gems, such as diamonds. Although crystallization is a ubiquitous phenomenon, exactly how crystals form remains a mystery. The building blocks — atoms, molecules or ions — that compose crystalline materials are highly ordered, forming lattices of equally spaced building blocks. These lattices then stack on top of each other to form a three-dimensional solid material.
“The stacking of atoms into regular arrangements is the reason that crystals have smooth, flat faces,” Luijten said. “That’s why they break along straight edges.”
Up until now, researchers have studied crystallization by examining much larger particles called colloids. But watching colloids self-arrange into crystals did not give insights into how atoms behave. Whereas crystals have flat, uniform surfaces, crystalline structures made from micron-sized colloids tend to adopt non-uniform, rough surfaces.
“Colloids are so much larger than atoms that it is doubtful they follow the same steps when crystallizing,” Luijten said. “So, they do not teach us what atoms do. The analogy of colloids to atoms doesn’t really hold.”
To glean deeper insights into the crystallization process, Luijten, Chen and their teams turned to nanoparticles. Recent advances to improve liquid-phase TEM have made it possible to view nanoparticles in real time as they form solid materials. Chen’s team spent years optimizing the process to ensure the electron beam could view the particles without damaging them. In the new study, the researchers used differently shaped nanoparticles — cubes, spheres and indented cubes — to explore how shape affects behavior.
The researchers first visualized crystal formation with advanced computer simulations, which were performed by Northwestern graduate students Ziwei Wang and Garrett Watson as well as postdoctoral fellow Tine Curk. Then they performed experiments with liquid-phase TEM to watch the nanoparticles self-assemble in real time. In the experiments, the researchers noticed the particles collided into each other, sticking together to form layers. Then, to form the layer-by-layer crystalline structure, the particles first formed a horizontal layer and then stacked vertically. Sometimes, after sticking to each other, the particles briefly detached to fall onto a layer below.
“They run along and then hesitate at the edge before falling,” Luijten said. “It’s like a diver hesitating at the edge of a diving board. I can’t believe we can actually see this. We have never seen the actual growth process before — only the result.”
Luijten said this information will help engineers design new materials. The insight specifically could help with the design of thin-film materials, which are often used to build flexible electronics, light-emitting diodes, transistors and solar cells.
“Knowing how particles come together will enable us to control the shape of a surface,” Luijten said. “Do you want a flat or rough surface? Changing particle shape or how fast the particles fall can affect the surface.”
Funding: Supported by the U.S. Department of Energy (award numbers DE-SC0020723 and DE-SC0020885) and the National Science Foundation (award number DGE-1842165).
Published in journal: Nature Nanotechnology
Source/Credit: Northwestern University | Amanda Morris
Reference Number: nt033023_01