A new technique produces perovskite nanocrystals right where they’re needed, so the exceedingly delicate materials can be integrated into nanoscale devices.
Researchers at MIT have developed a groundbreaking method for precisely growing halide perovskite nanocrystals, eliminating the need for damaging fabrication techniques. The technique aids in the development of nanoLEDs and other functional nanoscale devices, holding potential for advancements in optical communication, computing, and high-resolution display technology.
Halide perovskites are a family of materials that have attracted attention for their superior optoelectronic properties and potential applications in devices such as high-performance solar cells, light-emitting diodes, and lasers.
These materials have largely been implemented into thin-film or micron-sized device applications. Precisely integrating these materials at the nanoscale could open up even more remarkable applications, like on-chip light sources, photodetectors, and memristors. However, achieving this integration has remained challenging because this delicate material can be damaged by conventional fabrication and patterning techniques.
To overcome this hurdle, MIT researchers created a technique that allows individual halide perovskite nanocrystals to be grown on-site where needed with precise control over location, to within less than 50 nanometers. (A sheet of paper is 100,000 nanometers thick.) The size of the nanocrystals can also be precisely controlled through this technique, which is important because size affects their characteristics. Since the material is grown locally with the desired features, conventional lithographic patterning steps that could introduce damage are not needed.
The technique is also scalable, versatile, and compatible with conventional fabrication steps, so it can enable the nanocrystals to be integrated into functional nanoscale devices. The researchers used this to fabricate arrays of nanoscale light-emitting diodes (nanoLEDs) — tiny crystals that emit light when electrically activated. Such arrays could have applications in optical communication and computing, lensless microscopes, new types of quantum light sources, and high-density, high-resolution displays for augmented and virtual reality.
“As our work shows, it is critical to develop new engineering frameworks for integration of nanomaterials into functional nanodevices. By moving past the traditional boundaries of nanofabrication, materials engineering, and device design, these techniques can allow us to manipulate matter at the extreme nanoscale dimensions, helping us realize unconventional device platforms important to addressing emerging technological needs,” says Farnaz Niroui, the EE Landsman Career Development Assistant Professor of Electrical Engineering and Computer Science (EECS), a member of the Research Laboratory of Electronics (RLE), and senior author of a new paper describing the work.
Niroui’s co-authors include lead author Patricia Jastrzebska-Perfect, an EECS graduate student; Weikun “Spencer” Zhu, a graduate student in the Department of Chemical Engineering; Mayuran Saravanapavanantham, Sarah Spector, Roberto Brenes, and Peter Satterthwaite, all EECS graduate students; Zheng Li, an RLE postdoc; and Rajeev Ram, professor of electrical engineering. The research was published on July 6 in the journal Nature Communications.
Tiny crystals, huge challenges
Integrating halide perovskites into on-chip nanoscale devices is extremely difficult using conventional nanoscale fabrication techniques. In one approach, a thin film of fragile perovskites may be patterned using lithographic processes, which require solvents that may damage the material. In another approach, smaller crystals are first formed in solution and then picked and placed from solution in the desired pattern.
“In both cases there is a lack of control, resolution, and integration capability, which limits how the material can be extended to nanodevices,” Niroui says.
Instead, she and her team developed an approach to “grow” halide perovskite crystals in precise locations directly onto the desired surface where the nanodevice will then be fabricated.
Core to their process is to localize the solution that is used in the nanocrystal growth. To do so, they create a nanoscale template with small wells that contain the chemical process through which crystals grow. They modify the surface of the template and the inside of the wells, controlling a property known as “wettability” so a solution containing perovskite material won’t pool on the template surface and will be confined inside the wells.
“Now, you have these very small and deterministic reactors within which the material can grow,” she says.
And that is exactly what happens. They apply a solution containing halide perovskite growth material to the template and, as the solvent evaporates, the material grows and forms a tiny crystal in each well.
A versatile and tunable technique
The researchers found that the shape of the wells plays a critical role in controlling the nanocrystal positioning. If square wells are used, due to the influence of nanoscale forces, the crystals have an equal chance of being placed in each of the well’s four corners. For some applications, that might be good enough, but for others, it is necessary to have a higher precision in the nanocrystal placement.
By changing the shape of the well, the researchers were able to engineer these nanoscale forces in such a way that a crystal is preferentially placed in the desired location.
As the solvent evaporates inside the well, the nanocrystal experiences a pressure gradient that creates a directional force, with the exact direction being determined using the well’s asymmetric shape.
“This allows us to have very high precision, not only in growth, but also in the placement of these nanocrystals,” Niroui says.
They also found they could control the size of the crystal that forms inside a well. Changing the size of the wells to allow more or less growth solution inside generates larger or smaller crystals.
They demonstrated the effectiveness of their technique by fabricating precise arrays of nanoLEDs. In this approach, each nanocrystal is made into a nanopixel which emits light. These high-density nanoLED arrays could be used for on-chip optical communication and computing, quantum light sources, microscopy, and high-resolution displays for augmented and virtual reality applications.
In the future, the researchers want to explore more potential applications for these tiny light sources. They also want to test the limits of how small these devices can be, and work to effectively incorporate them into quantum systems. Beyond nanoscale light sources, the process also opens up other opportunities for developing halide perovskite-based on-chip nanodevices.
Their technique also provides an easier way for researchers to study materials at the individual nanocrystal level, which they hope will inspire others to conduct additional studies on these and other unique materials.
“Studying nanoscale materials through high-throughput methods often requires that the materials are precisely localized and engineered at that scale,” Jastrzebska-Perfect adds. “By providing that localized control, our technique can improve how researchers investigate and tune the properties of materials for diverse applications.”
“The team has developed a very clever method for deterministic synthesis of individual perovskite nanocrystals on substrates. They can control the exact placement of the nanocrystals in an unprecedented scale, thus enabling a platform for fabrication of highly efficient, nanoscale LEDs based on single nanocrystals,” says Ali Javey, professor of electrical engineering and computer sciences at the University of California at Berkeley, who was not involved with this research. “It is an exciting work as it overcomes a fundamental challenge in the field.”
Reference: “On-site growth of perovskite nanocrystal arrays for integrated nanodevices” by Patricia Jastrzebska-Perfect, Weikun Zhu, Mayuran Saravanapavanantham, Zheng Li, Sarah O. Spector, Roberto Brenes, Peter F. Satterthwaite, Rajeev J. Ram and Farnaz Niroui, 6 July 2023, Nature Communications.
DOI: 10.1038/s41467-023-39488-0
This work was supported, in part, by the National Science Foundation and the MIT Center for Quantum Engineering.