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Ligand Locking on Quantum Dot Surfaces via a Mild Reactive Surface Treatment

Anna Loiudice, Ona Segura Lecina, Aurélien Bornet, Joseph M. Luther, Raffaella Buonsanti

2021Journal of the American Chemical Society35 citationsDOIOpen Access PDF

Abstract

At the outermost surface of colloidal QDs are organic surface ligands which dynamically bind and release in solution to control the growth kinetics, control the size/shape of the crystals, passivate surface states, and provide colloidal stability through favorable interactions with the solvent. However, the dynamicity comes at the expense of the stability of the QD suspension. Here, we show that ligands can be permanently locked on the QD surface by a thin layer of an inert metal oxide which forms within the ligand shell, over the headgroup. By interrogating the surface chemistry with different spectroscopic methods, we prove the ligand locking on the QD surface. As a result, an exceptional stability of the coated QD inks is achieved in a wide concentration range, even in the presence of chemically competing surface ligands in solution. We anticipate that this critical breakthrough will benefit different areas related to colloidal QDs, spanning from single-particle studies to displays and solar cells and biological applications. Furthermore, the same chemistry could be easily translated to surface treatments of bulk materials and thin films.

Topics & Concepts

ChemistryColloidLigand (biochemistry)Quantum dotInertPassivationNanotechnologyParticle (ecology)Surface modificationKineticsChemical engineeringOxideNanoparticleMetalLayer (electronics)Physical chemistryOrganic chemistryMaterials sciencePhysicsReceptorEngineeringBiochemistryOceanographyGeologyQuantum mechanicsQuantum Dots Synthesis And PropertiesElectronic and Structural Properties of OxidesGold and Silver Nanoparticles Synthesis and Applications
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