Quantum dot light-emitting diodes (QLEDs) have made rapid progress in luminescence, efficiency, and stability, making them promising candidates for displays and solid-state lighting applications. However, achieving high-performance QLEDs with high color purity remains a persistent challenge, particularly red QLEDs, thus limiting the popularity of ultra-high definition devices. Recently, Soochow University, in collaboration with Macau University of Science and Technology and other research institutes, reported a facile high-temperature successive ion layer adsorption and reaction (HT-SILAR) strategy for the growth of high-quality, large-particle, alloyed red QDs. These QDs exhibit a near-unity photoluminescence quantum yield (PLQY), and narrow emission with a full width at half maximum (FWHM) of 17.1 nm. As a result, a record external quantum efficiency (EQE) of 38.2%, luminance over 120,000 cd m⁻², and exceptional operational stability T₉₅ (tested at 1,000 cd m⁻²) of 24,100 hours were achieved for QLEDs. This work opens new avenues for synthesizing high-quality QDs with high color purity and was published in Science Bulletin.

Pharmaceutical scientists at the National University of Singapore (NUS) have developed a novel chemical reaction that enables the precise functionalisation of peptides and proteins. This approach could provide a useful tool for bioconjugation and drug discovery.

Chemical modification of biomolecules is a powerful strategy for augmenting their functions. For example, antibody-drug conjugates use targeted antibodies to deliver highly cytotoxic drugs directly to tumour sites, while receptor ligand peptides armed with MRI agents improve medical imaging. However, selectively modifying proteins remains a significant challenge. Proteins are large molecules with many functional groups of similar reactivity, making it difficult to achieve precise modifications. Often, these reactions lead to complex mixtures that are difficult to control, poorly reproducible, and may include components with unintended effects.

The team led by Assistant Professor Alexander VINOGRADOV from the NUS Department of Pharmacy and Pharmaceutical Sciences and Professor Hiroaki SUGA from the University of Tokyo, Japan have developed a palladium-mediated reaction that overcomes some of these challenges.