Electrochemical Multiplexing: Control over Surface Functionalization by Combining a Redox‐Sensitive Alkyne Protection Group with “Click”‐Chemistry

Hellstern, Manuel; Gantenbein, Markus; Puebla‐Hellmann, Gabriel; Lörtscher, Emanuel; Mayor, Marcel

doi:10.1002/admi.201801917

Cited by 7 publications

(6 citation statements)

References 69 publications

(102 reference statements)

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“…We reasoned that a multi-modal ligand scaffold based on a bidentate 1,8-anthracendiyl backbone would provide both high binding affinity for the surface and strong electronic coupling to the QD excited state. Multidentate ligands, including scaffolds made from citric acid, 15 EDTA, 16 or multidentate polymers, 17 are known to have greater surface binding affinities than monodentate carboxylate ligands. However, carboxylate ligands, such as 9-ACA do not readily displace the native octadecylphosphonic acid (ODPA) from the surface of CdSe QDs.…”

Section: Main Textmentioning

confidence: 99%

Anthracene Diphosphate Ligands for CdSe Quantum Dots; Molecular Design for Efficient Upconversion

et al. 2020

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Quantum dot (QD) sensitized photon upconversion follows a multi-step energy transfer process from QD to transmitter ligand to a soluble annihilator. Using a novel 10-R-anthracene-1,8diphosphoric acid (R = octyl, 2-hexyldecyl, phenyl) ligand with high binding affinity for CdSe quantum dot (QD) surfaces, we demonstrate a photon upconversion process that is limited by the transmitter to annihilator transfer efficiency. Using 1 H NMR spectroscopy we demonstrate that these bidentate diphosphate ligands rapidly and irreversibly displace two carboxylate ligands. These ligands mediate energy transfer from the photoexcited QDs to a triplet annihilator (1,10-diphenylanthracene), producing overall photon upconversion quantum efficiencies as high as 17%, the highest for QDs with no shells. Transient absorption spectroscopy shows that the ADP ligand supports a 3.4 fold longer triplet state lifetime compared to 9-ACA (299.9 ± 9.5 vs 88.2 ± 2.1 μs), increasing the probability of the energy transfer.

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Section: Main Textmentioning

confidence: 99%

Anthracene Diphosphate Ligands for CdSe Quantum Dots; Molecular Design for Efficient Upconversion

et al. 2020

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“…The Mattoussi group has been very successful in designing and synthesizing polymeric ligands based on carboxylic acid, catechol, thiol, phosphonic acid, etc . In the realm of small molecules, there are multidentate carboxylate ligands derived from citric acid or EDTA. , One can also classify the zwitterionic ligands for CsPbBr 3 nanocrystals as multidentate. , The bisphosphonate ligand class has been successful in stabilizing various nanocrystals in water. − In our recent work, we focused on multidentate phosphates. The first generation comprised 10-R-anthracene-1,8-diphosphoric acid (R = octyl, 2-hexyldecyl, phenyl) derivatives; see Figure A.…”

Section: Ligand Design Toward High Binding Affinitymentioning

confidence: 99%

The Surface Chemistry of Colloidal Nanocrystals Capped by Organic Ligands

Roo

2023

Chem. Mater.

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Nanocrystal surface chemistry is a pivotal element in the synthesis and application of nanocrystals. This perspective focuses on colloidal nanocrystals, capped with organic ligands. We start with insights into a workhorse characterization technique: solution nuclear magnetic resonance (NMR) spectroscopy. We then discuss the different models used to conceptualize nanocrystal surface chemistry and how the classification of binding motifs helps in the prediction of surface reactions. The thermodynamics and kinetics of these surface reactions are analyzed, and we arrive at the deciding factors for a high binding affinity: sterics, pK a/pK b, and solubility/solvent. Finally, we discuss recent ligand designs; most notably we introduce a new ligand class: monoalkyl phosphinic acids.

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“…NDIs have functioned as anion‐π [5, 26–28] catalysts, [25] ion channels, [28, 29] sensors, [29] artificial photosystems, [6, 8, 30] semi‐conductors, [6, 31] G‐quartet stabilizers, [32] and self‐assembled matter in all variations, such as vesicles, [33] nanotubes, [34] mono‐ and multilayers on surfaces, [8, 30, 33] dynamic covalent libraries, knotted molecular topologies or donor‐acceptor stacks [33–36] . COC‐NDIs will be of interest to explore within this existing functional space, particularly with regard to artificial photosystems [8] .…”

Section: Figurementioning

confidence: 99%

Naphthalenediimides with Cyclic Oligochalcogenides in Their Core

Shybeka

Aster

Cheng

et al. 2020

Chemistry A European J

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Naphthalenediimides (NDIs) are privileged scaffolds par excellence, of use in functional systems from catalysts to ion channels, photosystems, sensors, ordered matter in all forms, tubes, knots, stacks, sheets, vesicles, and colored over the full visible range. Despite this extensively explored chemical space, there is still room to discover core‐substituted NDIs with fundamentally new properties: NDIs with cyclic trisulfides (i.e., trisulfanes) in their core absorb at 668 nm, emit at 801 nm, and contract into disulfides (i.e., dithietes) upon irradiation at <475 nm. Intramolecular 1,5‐chalcogen bonds account for record redshifts with trisulfides, ring‐tension mediated chalcogen‐bond‐mediated cleavage for blueshifts to 492 nm upon ring contraction. Cyclic oligochalcogenides (COCs) in the NDI core open faster than strained dithiolanes as in asparagusic acid and are much better retained on thiol exchange affinity columns. This makes COC‐NDIs attractive not only within the existing multifunctionality, particularly artificial photosystems, but also for thiol‐mediated cellular uptake.

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Electrochemical Multiplexing: Control over Surface Functionalization by Combining a Redox‐Sensitive Alkyne Protection Group with “Click”‐Chemistry

Cited by 7 publications

References 69 publications

Anthracene Diphosphate Ligands for CdSe Quantum Dots; Molecular Design for Efficient Upconversion

Anthracene Diphosphate Ligands for CdSe Quantum Dots; Molecular Design for Efficient Upconversion

The Surface Chemistry of Colloidal Nanocrystals Capped by Organic Ligands

Naphthalenediimides with Cyclic Oligochalcogenides in Their Core

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