Optical Sensing of Anions via Supramolecular Recognition with Biimidazole Complexes

Rommel, Sebastian A.; Sorsche, Dieter; Fleischmann, M.; Rau, Sven

doi:10.1002/chem.201605782

Cited by 39 publications

(27 citation statements)

References 98 publications

(182 reference statements)

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“…Although Ru II complexes are potent sensing units featuring highly beneficial charge assistance of XBs, [13b, c, 20b] their twofold cationic charge may induce solubility issues as well as unspecific electrostatic interactions to reach charge neutrality in organic solvent mixtures. Hence, the structurally related but monocationic congener [Ir(bpy)(ppy) 2 ] + (ppy=phenylpyridine) is an attractive alternative [19] .…”

Section: Introductionmentioning

confidence: 99%

Facile and Reliable Emission‐Based Nanomolar Anion Sensing by Luminescent Iridium Receptors Featuring Chelating Halogen‐Bonding Sites

Kampes

Tepper

Görls

et al. 2020

Chemistry A European J

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An anion sensor is presented that combinesabidentateh ydrogen-(HB) or halogen-bonding (XB) site with a luminescent monocationic Ir fragment for strongb inding of common anions (K a up to 6 10 4 m À1)w ith diagnostice mission changes. An ew emission-based protocol for fast and reliabled etection was derived on the basis of correction for systematic but unspecificb ackground effects. Such as imple correction routine circumvents the hitherto practical limitations of systematic emission-based analysis of anion binding with validated open-source software (BindFit).T he anticipated order of K a values was obeyed according to size and ba-sicity of the anions(Cl > Br = OAc) as well as the donor atom of the receptor (XB:6 10 4 m À1 > HB:5 10 3 m À1), and led to submicromolar limitso fd etection within minutes.T he results were further validated by advanced NMR techniques, and corroborated by X-ray crystallographic dataa nd DFT analysis, which reproduced the structural and electronic features in excellent agreement. The resultss uggest that correctedemission-baseds ensingm ay become ac omplementary,r eliable, and fast tool to promote the use of XB in various application fields,d ue to the simple and fast opticald etermination at high dilution.

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Section: Introductionmentioning

confidence: 99%

Facile and Reliable Emission‐Based Nanomolar Anion Sensing by Luminescent Iridium Receptors Featuring Chelating Halogen‐Bonding Sites

Kampes

Tepper

Görls

et al. 2020

Chemistry A European J

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“…Finally, the simple mix‐&‐read test‐strip assay demonstrated that this approach is very appealing for powerful and reliable analytics for everyday life in a relevant concentration range. If one considers that over the past four decades a vast number of small‐molecule probes for a large number of analytes have been reported in the literature, of which, however, only a few operate in neat aqueous solution, reconsideration of one or the other probe molecules and combination with suitably tailored nanomaterials in view of our present work might lead in a rather straightforward manner to various other potent indicator materials for comparatively simple analytical applications.…”

Section: Discussionmentioning

confidence: 99%

Mix‐&‐Read Determination of Mercury(II) at Trace Levels with Hybrid Mesoporous Silica Materials Incorporating Fluorescent Probes by a Simple Mix‐&‐Load Technique

et al. 2018

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The synthesis, characterization, and application of mesoporous materials containing boron–dipyrromethene (BODIPY) moieties that allow the sensitive and selective detection of HgII in aqueous environments by fluorescence enhancement is reported. For this purpose, BODIPY dye I containing a thia‐aza crown ether receptor as the fluorescent probe for the detection of HgII in aqueous environments is encapsulated into mesoporous materials to avoid self‐quenching or aggregation in water. Determination of HgII is accomplished within a few seconds with high selectivity and sensitivity, reaching a limit of detection of 12 ppt. The determination of trace amounts of HgII in natural waters and in fish extracts is demonstrated by using our sensing material. The incorporation of the material into several μ‐PAD strips yields a portable, cheap, quick, and easy‐to‐handle tool for trace HgII analysis in water.

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“…The binding interaction is authenticated from single-crystal X-ray structure of new Mo(VI) complex (M1). The sequential detection limits for AsO 2 – and H 2 PO 4 – are 1.2 × 10 –10 and 3.2 × 10 –6 M, respectively, whereas the corresponding binding constants are 6.49 × 10 4 and 2.11 × 10 5 M –1 .…”

Section: Introductionmentioning

confidence: 96%

Sequential Fluorescence Recognition of Molybdenum(VI), Arsenite, and Phosphate Ions in a Ratiometric Manner: A Facile Approach for Discrimination of AsO₂^–and H₂PO₄^–

Banerjee

Ghosh

et al. 2019

ACS Omega

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An amide-based smart probe (L) is explored for nanomolar detection of Mo(VI) ion in a ratiometric manner, involving hydrogen-bond-assisted chelation-enhanced fluorescence process through inhibition of photoinduced electron transfer process. The recognition of Mo(VI) is associated with a 17-fold fluorescence enhancement and confirmed by single-crystal X-ray diffraction of the resulting Mo(VI) complex (M1). Further, M1 selectively recognizes arsenite through green emission of their adduct (C1) with an 81-fold fluorescence enhancement. Interestingly, dihydrogen phosphate causes dissociation of C1 back to free L having weak fluorescence. The methods are fast, highly selective, and allow their bare eye visualization at physiological pH. All of the interactions have been substantiated by time-dependent density functional theory calculations to rationalize their spectroscopic properties. The corresponding lowest detection limits are 1.5 × 10 –8 M for Mo(VI), 1.2 × 10 –10 M for AsO 2 – , and 3.2 × 10 –6 M for H 2 PO 4 – , whereas the respective association constants are 4.21 × 10 5 M –1 for Mo(VI), 6.49 × 10 4 M –1 for AsO 2 – , and 2.11 × 10 5 M –1 for H 2 PO 4 – . The L is useful for efficient enrichment of Mo(VI) from aqueous solution, while M1 efficiently removes AsO 2 – from environmental samples by solid-phase extraction.

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Optical Sensing of Anions via Supramolecular Recognition with Biimidazole Complexes

Cited by 39 publications

References 98 publications

Facile and Reliable Emission‐Based Nanomolar Anion Sensing by Luminescent Iridium Receptors Featuring Chelating Halogen‐Bonding Sites

Facile and Reliable Emission‐Based Nanomolar Anion Sensing by Luminescent Iridium Receptors Featuring Chelating Halogen‐Bonding Sites

Mix‐&‐Read Determination of Mercury(II) at Trace Levels with Hybrid Mesoporous Silica Materials Incorporating Fluorescent Probes by a Simple Mix‐&‐Load Technique

Sequential Fluorescence Recognition of Molybdenum(VI), Arsenite, and Phosphate Ions in a Ratiometric Manner: A Facile Approach for Discrimination of AsO₂^–and H₂PO₄^–

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Optical Sensing of Anions via Supramolecular Recognition with Biimidazole Complexes

Cited by 39 publications

References 98 publications

Facile and Reliable Emission‐Based Nanomolar Anion Sensing by Luminescent Iridium Receptors Featuring Chelating Halogen‐Bonding Sites

Facile and Reliable Emission‐Based Nanomolar Anion Sensing by Luminescent Iridium Receptors Featuring Chelating Halogen‐Bonding Sites

Mix‐&‐Read Determination of Mercury(II) at Trace Levels with Hybrid Mesoporous Silica Materials Incorporating Fluorescent Probes by a Simple Mix‐&‐Load Technique

Sequential Fluorescence Recognition of Molybdenum(VI), Arsenite, and Phosphate Ions in a Ratiometric Manner: A Facile Approach for Discrimination of AsO2–and H2PO4–

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Sequential Fluorescence Recognition of Molybdenum(VI), Arsenite, and Phosphate Ions in a Ratiometric Manner: A Facile Approach for Discrimination of AsO₂^–and H₂PO₄^–