LMU’s Gemini Ligands Stabilize Quantum Dots in Polar Solvents

Researchers at LMU have overcome a critical limitation hindering the widespread use of perovskite quantum dots: their rapid disintegration in common polar solvents like alcohols.

The team stabilized these promising materials for LEDs, photocatalysis, and quantum light sources using newly developed “Gemini ligands” that create a polar external surface while binding to the dots themselves. These ligands allow the quantum dots to disperse stably in solvents like ethanol, while maintaining exceptionally thin layers of around 0.7 nanometers to preserve optical properties. “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. The findings, published in both the Journal of the American Chemical Society and ACS Energy Letters, also detail a method for controlling quantum dot growth with sub-unit-cell precision.

Gemini Ligands Stabilize Perovskite Quantum Dots in Polar Solvents Perovskite quantum dots, candidates for LEDs and photocatalytic systems, have long suffered from a critical flaw: polar solvents like alcohols cause them to rapidly disintegrate, severely limiting their practical application.

The team’s approach centers on “Gemini ligands,” molecules engineered to create a protective shell around the quantum dots while simultaneously altering their surface properties. These ligands bind to the quantum dots via charged groups, effectively stabilizing them against solvent attack, and crucially, form a polar external surface, allowing for stable dispersion in solvents previously considered incompatible. Unlike earlier stabilization methods, this ligand layer remains exceptionally thin, measuring approximately 0.7 nanometers, preserving the desirable optical characteristics of the perovskite material. The resulting stabilized quantum dots maintain high photoluminescence quantum yields and exhibit prolonged preservation in solution, opening the door to processing with environmentally friendly “green solvents,” a significant advantage for future optoelectronic manufacturing. This improved stability enables new fabrication techniques and broadens the range of potential applications for these nanoscale semiconductors.

Controlled Growth Achieves Sub-Unit-Cell Precision in CsPbBr₃ Quantum Dots Perovskite quantum dots, already recognized for their potential in applications ranging from light-emitting diodes to photocatalysis, have historically faced limitations regarding both stability and precise manufacturing control. Recent work from Ludwig Maximilian University (LMU) in Munich addresses both challenges simultaneously, promising to broaden the scope of these materials. While comparatively simple to create in solution, the inherent softness of the perovskite crystal lattice renders these nanometer-scale semiconductors vulnerable to degradation, particularly when exposed to common polar solvents like alcohols, causing rapid disintegration. Researchers have now demonstrated a method to not only stabilize the dots in such solvents but also to control their growth with unprecedented accuracy. This stabilizing layer measures only 0.7 nanometers thick, preserving the quantum dots’ inherent optical properties, as Akkerman noted. Beyond stabilization, the researchers achieved sub-unit-cell precision in controlling quantum dot growth, meaning they can dictate size and structure to within the dimensions of a single crystal lattice cell. This level of control was accomplished through a multi-stage injection strategy, suppressing the formation of new crystals and encouraging existing ones to grow in a coordinated manner, influencing reaction kinetics with carefully selected ligands. The resulting quantum dots exhibit remarkably narrow size distributions and consistently stable optical properties, essential characteristics for advanced optoelectronic devices and potential quantum light sources, opening new possibilities for applications in these fields. “A challenge to date has been keeping the quantum dots stable without impairing their structural and optical properties,” Source: https://www.lmu.de/en/newsroom/news-overview/news/quantum-dots-for-light-technologies-of-the-future-5eba21b6.html Tags: Ivy Delaney We've seen the rise of AI over the last few short years with the rise of the LLM and companies such as Open AI with its ChatGPT service. Ivy has been working with Neural Networks, Machine Learning and AI since the mid nineties and talk about the latest exciting developments in the field. Latest Posts by Ivy Delaney: Quantum Computers Edge Closer with Universal Noise Reduction Technique April 22, 2026 QGI’s Q-Prime Embeds Data in Quantum-Structured Hypergraph April 22, 2026 IBM Quantum System Two Arrives in Chicago This September April 22, 2026