Quantum dots for light technologies of the future

Although perovskite quantum dots are comparatively easy to manufacture in solution, their soft ionic crystal lattices make them sensitive to many solvents.
Photo Credit: © Johanna Weber

Scientific Frontline: Extended "At a Glance" Summary: Perovskite Quantum Dots

The Core Concept: Perovskite quantum dots are nanometer-sized semiconductor crystals that harness quantum effects to efficiently absorb and re-emit light. Composed primarily of metals and halides, these nanocrystals possess highly customizable optical and electronic characteristics dictated by their extremely small dimensions.

Key Distinction/Mechanism: Historically, perovskite quantum dots have been hindered by soft ionic crystal lattices that rapidly disintegrate in polar solvents like alcohols. Novel methodologies utilize Gemini ligands to form an ultra-thin, stable molecular shell (approximately 0.7 nanometers) around the dots, allowing robust dispersion in polar and "green" solvents while preserving photoluminescence. Additionally, new kinetic reaction controls enable these dots to grow with sub-unit-cell precision, rather than unpredictably forming new seed crystals.

Major Frameworks/Components:

• Perovskite Material Lattices: Metal and halide combinations forming the core semiconductor structure.
• Gemini Ligand Chemistry: Charged molecular groups that bind to the nanocrystal's surface, establishing a protective, polar external surface for chemical stability.
• Reaction Kinetics Control: A multi-stage injection strategy that dictates the precise chemical environment, suppressing random seed formation.
• Sub-unit-cell Precision Growth: Engineering crystal overgrowth at a scale smaller than an individual crystal lattice cell, ensuring exceptionally narrow size distribution.

Branch of Science: Nanotechnology, Materials Science, Physical Chemistry, Quantum Physics, and Optoelectronics.

Future Application: The development of highly efficient light-emitting diodes (LEDs), advanced photocatalysis, robust quantum light sources, and integration into sustainable, green-solvent manufacturing processes.

Why It Matters: Solving the fragility of perovskite quantum dots in solution clears a primary bottleneck in their commercialization. Precise atomic-level tuning combined with the ability to process these materials in eco-friendly solvents accelerates the timeline for next-generation optoelectronic and quantum light technologies.

Dr. Kushagra Gahlot, M. Sc. Lena Stickel and Dr. Quinten Akkerman
Photo Credit: © Johanna Weber

Perovskite quantum dots are considered promising materials for LEDs, photocatalysis, and future quantum light sources. Researchers at LMU have managed to master two major hurdles in working with these quantum dots: their stability in solution and precise control of their growth. Their results could open new avenues for the processing and application of the materials, as the team reports in the Journal of the American Chemical Society and ACS Energy Letters. 

Quantum dots rapidly disintegrate in polar solvents 

Perovskite quantum dots are semiconductor crystals just a few nanometers in size. They consist of perovskite materials, usually a combination of metals and halides. Due to their extremely small dimensions, they exhibit quantum effects which strongly alter their optical and electronic characteristics. This allows them to absorb and re-emit light very efficiently. 

Although perovskite quantum dots are comparatively easy to manufacture in solution, their soft ionic crystal lattices make them sensitive to many solvents. Particularly problematic are polar solvents like alcohol, in which quantum dots often disintegrate quite rapidly. 

“A challenge to date has been keeping the quantum dots stable without impairing their structural and optical properties,” says Dr. Quinten Akkerman from the Nano-Institute Munich and the Faculty of Physics at LMU. Together with his team, Akkerman has developed a strategy to get around these limitations. 

Dr. Quinten Akkerman
Photo Credit: © Johanna Weber

Stabilization in solution – thanks to new ligand chemistry 

The scientists used so-called Gemini ligands, which form a stable molecular shell around quantum dots. They bind with their charged groups to the surface of the quantum dots, while at the same time their structure forms a polar external surface. This allows quantum dots to disperse in a stable manner in polar solvents like ethanol. The ligand layer remains exceptionally thin at around 0.7 nanometers, such that the optical properties of the quantum dots are preserved. 

The stabilized quantum dots continue to exhibit high photoluminescence quantum yields and remain preserved in solution for long periods of time. At the same time, they can now be processed in so-called green solvents – an advantage for future manufacturing processes in optoelectronics. 

Growth of quantum dots with atomic precision 

In a second study, the team addressed the question of how to precisely control the size and structure of perovskite quantum dots. These properties determine what color and intensity the quantum dots emit. 

Akkerman’s team developed a method by which the formation of new seed crystals is specifically suppressed. Instead, existing quantum dots grow in a controlled manner. This becomes possible through precise coordination of the reaction conditions and the ligands employed, which influence the reaction kinetics. 

With a multi-stage injection strategy, the researchers were able to control the growth of quantum dots over longer periods. They even achieved sub-unit-cell precision – that is to say, with a precision smaller than an individual crystal lattice cell. 

The quantum dots generated in this fashion exhibit particularly narrow size distribution and stable optical properties. Such controlled structures are an important precondition for use in LEDs or future quantum light applications. 

Prospects for optoelectronics and quantum light 

“Together, the two studies provide new approaches for solving challenges relating to perovskite quantum dots,” says Akkerman. “While the new ligand chemistry improves their processing and stability, the precise control of their growth enables precise tuning of their optical properties.” This opens new possibilities for applications in optoelectronics and future quantum light technologies. 

Published in journal:

1. Journal of the American Chemical Society
2. ACS Energy Letters

Title:

1. Unlocking Subunit Cell Precision Overgrowth in CsPbBr3 Quantum Dots
2. Polar Opposites: Ligand-Mediated Polarity Inversion for Perovskite Quantum Dots with Sub-Nanometer Ligand Shells

Authors: 

1. Kushagra Gahlot, David Ederle, Lena S. Stickel, Markus Döblinger, and Quinten A. Akkerman
2. Fei He, Lena S. Stickel, Markus Döblinger, and Quinten A. Akkerman

Source/Credit: Ludwig-Maximilians-Universität München

Reference Number: nt042126_01

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