Investigation of the Co-Dependence of Morphology and Fluorescence Lifetime in a Metal-Organic Framework

Porous materials, due to their large surface‐to‐volume ratio, are important for a broad range of applications and are the subject of intense research. Most studies investigate the bulk properties of these materials, which are not sensitive to the effect of heterogeneities within the sample. Herein,...

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Published in	Small (Weinheim an der Bergstrasse, Germany) Vol. 12; no. 27; pp. 3651 - 3657
Main Authors	Schrimpf, Waldemar, Ossato, Giulia, Hirschle, Patrick, Wuttke, Stefan, Lamb, Don C.
Format	Journal Article
Language	English
Published	Germany Blackwell Publishing Ltd 01.07.2016 Wiley Subscription Services, Inc
Subjects	Correlation correlative microscopy Dependence electron microscopy Fluorescence fluorescence lifetime imaging Heterogeneity Metal-organic frameworks Morphology Nanotechnology phasors Porous materials Quenching Scanning electron microscopy Service life assessment phasors correlative microscopy electron microscopy fluorescence lifetime imaging metal-organic frameworks
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Abstract	Porous materials, due to their large surface‐to‐volume ratio, are important for a broad range of applications and are the subject of intense research. Most studies investigate the bulk properties of these materials, which are not sensitive to the effect of heterogeneities within the sample. Herein, a new strategy based on correlative fluorescence lifetime imaging and scanning electron microscopy is presented that allows the detection and localization of those heterogeneities, and connects them to morphological and structural features of the material. By applying this method to a dye‐modified metal‐organic framework (MOF), two independent fluorescence quenching mechanisms in the MOF scaffold are identified and quantified. The first mechanism is based on quenching via amino groups, while the second mechanism is influenced by morphology. Furthermore, a similar correlation between the inherent luminescence lifetime and the morphology of the unmodified MOF structure is demonstrated. A novel approach to elucidate the structural, functional, and morphological properties of (in)organic materials using correlative fluorescence lifetime image microscopy and scanning electron microscopy is presented. Using this method, a correlation between the morphology and the fluorescence lifetime in a metal‐organic framework (MOF) is shown. Additionally, two quenching mechanisms of fluorescein in this MOF are identified and quantified.
AbstractList	Porous materials, due to their large surface‐to‐volume ratio, are important for a broad range of applications and are the subject of intense research. Most studies investigate the bulk properties of these materials, which are not sensitive to the effect of heterogeneities within the sample. Herein, a new strategy based on correlative fluorescence lifetime imaging and scanning electron microscopy is presented that allows the detection and localization of those heterogeneities, and connects them to morphological and structural features of the material. By applying this method to a dye‐modified metal‐organic framework (MOF), two independent fluorescence quenching mechanisms in the MOF scaffold are identified and quantified. The first mechanism is based on quenching via amino groups, while the second mechanism is influenced by morphology. Furthermore, a similar correlation between the inherent luminescence lifetime and the morphology of the unmodified MOF structure is demonstrated. Porous materials, due to their large surface‐to‐volume ratio, are important for a broad range of applications and are the subject of intense research. Most studies investigate the bulk properties of these materials, which are not sensitive to the effect of heterogeneities within the sample. Herein, a new strategy based on correlative fluorescence lifetime imaging and scanning electron microscopy is presented that allows the detection and localization of those heterogeneities, and connects them to morphological and structural features of the material. By applying this method to a dye‐modified metal‐organic framework (MOF), two independent fluorescence quenching mechanisms in the MOF scaffold are identified and quantified. The first mechanism is based on quenching via amino groups, while the second mechanism is influenced by morphology. Furthermore, a similar correlation between the inherent luminescence lifetime and the morphology of the unmodified MOF structure is demonstrated. A novel approach to elucidate the structural, functional, and morphological properties of (in)organic materials using correlative fluorescence lifetime image microscopy and scanning electron microscopy is presented. Using this method, a correlation between the morphology and the fluorescence lifetime in a metal‐organic framework (MOF) is shown. Additionally, two quenching mechanisms of fluorescein in this MOF are identified and quantified. Porous materials, due to their large surface-to-volume ratio, are important for a broad range of applications and are the subject of intense research. Most studies investigate the bulk properties of these materials, which are not sensitive to the effect of heterogeneities within the sample. Herein, a new strategy based on correlative fluorescence lifetime imaging and scanning electron microscopy is presented that allows the detection and localization of those heterogeneities, and connects them to morphological and structural features of the material. By applying this method to a dye-modified metal-organic framework (MOF), two independent fluorescence quenching mechanisms in the MOF scaffold are identified and quantified. The first mechanism is based on quenching via amino groups, while the second mechanism is influenced by morphology. Furthermore, a similar correlation between the inherent luminescence lifetime and the morphology of the unmodified MOF structure is demonstrated. A novel approach to elucidate the structural, functional, and morphological properties of (in)organic materials using correlative fluorescence lifetime image microscopy and scanning electron microscopy is presented. Using this method, a correlation between the morphology and the fluorescence lifetime in a metal-organic framework (MOF) is shown. Additionally, two quenching mechanisms of fluorescein in this MOF are identified and quantified.
Author	Hirschle, Patrick Wuttke, Stefan Lamb, Don C. Schrimpf, Waldemar Ossato, Giulia
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Cites_doi	10.1002/anie.200900339 10.1002/anie.201106651 10.1039/B618320B 10.1002/anie.201205627 10.1039/C4CC02650K 10.1021/cr200324t 10.2116/analsci.31.275 10.1016/j.bpj.2013.05.059 10.1039/C4CS90059F 10.1021/cm502920f 10.1529/biophysj.107.120154 10.1002/chem.201203491 10.1126/science.1230444 10.1007/BF00866388 10.1002/chem.201406157 10.1021/cs400959k 10.1039/C39860001709 10.1021/cr300014x 10.1039/c2jm16030g 10.1038/srep05418 10.1021/ja503218j 10.1002/anie.201410252 10.1038/ncomms1714 10.1021/cr200179u 10.1038/srep02562 10.1111/j.1365-2818.2004.01265.x 10.1021/cm103644b 10.1002/anie.201311128 10.1016/j.micromeso.2012.06.044 10.1088/0967-3334/26/4/N01 10.1007/s10895-005-2990-8
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Snippet	Porous materials, due to their large surface‐to‐volume ratio, are important for a broad range of applications and are the subject of intense research. Most... Porous materials, due to their large surface-to-volume ratio, are important for a broad range of applications and are the subject of intense research. Most...
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SubjectTerms	Correlation correlative microscopy Dependence electron microscopy Fluorescence fluorescence lifetime imaging Heterogeneity Metal-organic frameworks Morphology Nanotechnology phasors Porous materials Quenching Scanning electron microscopy Service life assessment
Title	Investigation of the Co-Dependence of Morphology and Fluorescence Lifetime in a Metal-Organic Framework
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