| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Infante, Ivan
Basque Center for Materials, Applications and Nanostructures
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (39/39 displayed)
- 2024Ultrafast nanocomposite scintillators based on Cd-enhanced CsPbCl$_3$ nanocrystals in polymer matrixcitations
- 2024Ultrafast Nanocomposite Scintillators Based on Cd-Enhanced CsPbCl3 Nanocrystals in Polymer Matrixcitations
- 2024Exogenous Metal Cations in the Synthesis of CsPbBr3 Nanocrystals and Their Interplay with Tertiary Aminescitations
- 2024Exogenous Metal Cations in the Synthesis of CsPbBr3 Nanocrystals and Their Interplay with Tertiary Aminescitations
- 2024Lead‐free halide perovskite materials and optoelectronic devices: progress and prospectivecitations
- 2023Lead-Free Halide Perovskite Materials and Optoelectronic Devices: Progress and Prospectivecitations
- 2023Light Emission from Low‐Dimensional Pb‐Free Perovskite‐Related Metal Halide Nanocrystalscitations
- 2023Lead‐Free Halide Perovskite Materials and Optoelectronic Devices: Progress and Prospectivecitations
- 2022Classical Force-Field Parameters for CsPbBr3Perovskite Nanocrystalscitations
- 2022Halide perovskites as disposable epitaxial templates for the phase-selective synthesis of lead sulfochloride nanocrystalscitations
- 2022Cu+→ Mn2+ Energy Transfer in Cu, Mn Coalloyed Cs3ZnCl5Colloidal Nanocrystalscitations
- 2022Classical Force-Field Parameters for CsPbBr 3 Perovskite Nanocrystalscitations
- 2021Sb-Doped Metal Halide Nanocrystals: A 0D versus 3D Comparisoncitations
- 2021Halide Perovskite-Lead Chalcohalide Nanocrystal Heterostructurescitations
- 2021Halide Perovskite-Lead Chalcohalide Nanocrystal Heterostructurescitations
- 2020Alloy CsCd x Pb 1- x Br 3 Perovskite Nanocrystals:The Role of Surface Passivation in Preserving Composition and Blue Emissioncitations
- 2020Nanocrystals of Lead Chalcohalides:A Series of Kinetically Trapped Metastable Nanostructurescitations
- 2020Alloy CsCd x Pb1-x Br3 Perovskite Nanocrystals: The Role of Surface Passivation in Preserving Composition and Blue Emissioncitations
- 2020Alloy CsCd xPb1- xBr3Perovskite Nanocrystalscitations
- 2020Near-Edge Ligand Stripping and Robust Radiative Exciton Recombination in CdSe/CdS Core/Crown Nanoplateletscitations
- 2020Near-edge ligand stripping and robust radiative exciton recombination in CdSe/CdS core/crown nanoplateletscitations
- 2020Nanocrystals of Lead Chalcohalidescitations
- 2020Cs 3 Cu 4 In 2 Cl 13 Nanocrystals:A Perovskite-Related Structure with Inorganic Clusters at A Sitescitations
- 2020Cs3Cu4In2Cl13 Nanocrystalscitations
- 2019Role of Surface Reduction in the Formation of Traps in n-Doped II-VI Semiconductor Nanocrystals: How to Charge without Reducing the Surfacecitations
- 2019Ruthenium-Decorated Cobalt Selenide Nanocrystals for Hydrogen Evolutioncitations
- 2019Fully Inorganic Ruddlesden-Popper Double Cl-I and Triple Cl-Br-I Lead Halide Perovskite Nanocrystalscitations
- 2019Role of Surface Reduction in the Formation of Traps in n-Doped II-VI Semiconductor Nanocrystalscitations
- 2019Stable Ligand Coordination at the Surface of Colloidal CsPbBr 3 Nanocrystalscitations
- 2019Stable Ligand Coordination at the Surface of Colloidal CsPbBr3 Nanocrystalscitations
- 2018Finding and Fixing Traps in II-VI and III-V Colloidal Quantum Dotscitations
- 2018Finding and Fixing Traps in II-VI and III-V Colloidal Quantum Dots: The Importance of Z-Type Ligand Passivationcitations
- 2018The Phosphine Oxide Route toward Lead Halide Perovskite Nanocrystalscitations
- 2018Finding and Fixing Traps in II-VI and III-V Colloidal Quantum Dots:The Importance of Z-Type Ligand Passivationcitations
- 2018Highly emissive self-trapped excitons in fully inorganic zero-dimensional tin halidescitations
- 2016Chemically Triggered Formation of Two-Dimensional Epitaxial Quantum Dot Superlatticescitations
- 2016Chemically Triggered Formation of Two-Dimensional Epitaxial Quantum Dot Superlatticescitations
- 2016Surface Termination, Morphology and Bright Photoluminescence of Cesium Lead Halide Perovskite Nanocrystalscitations
- 2016Surface Termination, Morphology and Bright Photoluminescence of Cesium Lead Halide Perovskite Nanocrystalscitations
Places of action
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article
Chemically Triggered Formation of Two-Dimensional Epitaxial Quantum Dot Superlattices
Abstract
Two dimensional superlattices of epitaxially connected quantum dots enable size-quantization effects to be combined with high charge carrier mobilities, an essential prerequisite for highly performing QD devices based on charge transport. Here, we demonstrate that surface active additives known to restore nanocrystal stoichiometry can trigger the formation of epitaxial superlattices of PbSe and PbS quantum dots. More specifically, we show that both chalcogen-adding (sodium sulfide) and lead oleate displacing (amines) additives induce small area epitaxial superlattices of PbSe quantum dots. In the latter case, the amine basicity is a sensitive handle to tune the superlattice symmetry, with strong and weak bases yielding pseudohexagonal or quasi-square lattices, respectively. Through density functional theory calculations and in situ titrations monitored by nuclear magnetic resonance spectroscopy, we link this observation to the concomitantly different coordination enthalpy and ligand displacement potency of the amine. Next to that, an initial ∼10% reduction of the initial ligand density prior to monolayer formation and addition of a mild, lead oleate displacing chemical trigger such as aniline proved key to induce square superlattices with long-range, square micrometer order; an effect that is the more pronounced the larger the quantum dots. Because the approach applies to PbS quantum dots as well, we conclude that it offers a reproducible and rational method for the formation of highly ordered epitaxial quantum dot superlattices. KEYWORDS: nanomaterials, PbSe, self-assembly, quantum-dot solid, surface chemistry C olloidal nanocrystals made by highly precise synthesis methods such as hot injection have been widely used as building blocks of self-assembled nanocrystal superlattices. 1−5 Especially in the case of semiconductor nanocrystals or quantum dots (QDs), formation of highly involved binary or ternary superstructures has been demon-strated, 6−10 the symmetry of which could be rationalized using hard sphere crystallization theory. 10−13 Whereas this provides ample possibilities to combine different nanocrystals in a single ordered crystal, only a few studies have shown such an approach to result in metamaterials with new or enhanced properties. 14−16 For one thing, this is due to the use of nanocrystal building blocks capped by long, organic ligands, which inevitably leads to electrically insulating nanocrystal solids. Therefore, optoelectronic devices, such as transis-tors, 17−19 solar cells, 20−23 or photodetectors, 24−26 are based on disordered QD solids, where the interparticle distance is usually decreased by exchanging the long organic ligands with shorter organic or inorganic moieties. 27−31 Although this makes for QD devices with ever increasing performance, carrier mobilities remain well below 10 cm 2 V −1 s −1 and the approach leaves no room for any symmetry-induced collective effects.