Surface-Anchored MOF-Based Photonic Antennae

The loading of a metal‐organic framework (MOF), [Cu3(btc)2xH2O] HKUST‐1, with europium β‐diketonate complexes is studied with the goal to using the porous molecular framework as a photonic antenna. Whereas loading of HKUST‐1 powder particles produced via the conventional solvothermal synthesis metho...

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Published inChemphyschem Vol. 13; no. 11; pp. 2699 - 2702
Main Authors Streit, Huayna Cerqueira, Adlung, Matthias, Shekhah, Osama, Stammer, Xia, Arslan, Hasan Kemal, Zybaylo, Olexandra, Ladnorg, Tatjana, Gliemann, Hartmut, Franzreb, Matthias, Wöll, Christof, Wickleder, Claudia
Format Journal Article
LanguageEnglish
Published Weinheim WILEY-VCH Verlag 06.08.2012
WILEY‐VCH Verlag
Wiley
Subjects
Chemistry
energy transfer
europium complexes
Exact sciences and technology
General and physical chemistry
luminescence
photonic antennae
Surface physical chemistry
surface-anchored metal-organic frameworks
Metal organic framework
photonic antenna
europium complexes
Rare earth metal complex
Luminescence
Organic ligand
Europium complex
Energy transfer
surface-anchored metalorganic frameworks
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Abstract The loading of a metal‐organic framework (MOF), [Cu3(btc)2xH2O] HKUST‐1, with europium β‐diketonate complexes is studied with the goal to using the porous molecular framework as a photonic antenna. Whereas loading of HKUST‐1 powder particles produced via the conventional solvothermal synthesis method was strongly hindered, for HKUST‐1 SURMOFs, thin MOF films fabricated using the liquid phase epitaxy method, a high filling factor can be achieved. The optical properties of the HKUST‐1‐MOFs before and after loading were analysed with the aid of luminescence spectroscopy. Careful analysis of the absorption spectra reveals the presence of an effective energy transfer between the HKUST‐1 framework and the Eu3+ centers. The optical properties of HKUST‐1 MOFs before and after loading a Eu3+ complex are analysed with the aid of luminescence spectroscopy (see graphic). The presence of an effective energy transfer between the HKUST‐1 framework and the Eu3+ centers was found as is described herein.
AbstractList Abstract The loading of a metal‐organic framework (MOF), [Cu 3 (btc) 2 x H 2 O] HKUST‐1, with europium β‐diketonate complexes is studied with the goal to using the porous molecular framework as a photonic antenna. Whereas loading of HKUST‐1 powder particles produced via the conventional solvothermal synthesis method was strongly hindered, for HKUST‐1 SURMOFs, thin MOF films fabricated using the liquid phase epitaxy method, a high filling factor can be achieved. The optical properties of the HKUST‐1‐MOFs before and after loading were analysed with the aid of luminescence spectroscopy. Careful analysis of the absorption spectra reveals the presence of an effective energy transfer between the HKUST‐1 framework and the Eu 3+ centers.
The loading of a metal-organic framework (MOF), [Cu(3)(btc)(2)xH(2)O] HKUST-1, with europium β-diketonate complexes is studied with the goal to using the porous molecular framework as a photonic antenna. Whereas loading of HKUST-1 powder particles produced via the conventional solvothermal synthesis method was strongly hindered, for HKUST-1 SURMOFs, thin MOF films fabricated using the liquid phase epitaxy method, a high filling factor can be achieved. The optical properties of the HKUST-1-MOFs before and after loading were analysed with the aid of luminescence spectroscopy. Careful analysis of the absorption spectra reveals the presence of an effective energy transfer between the HKUST-1 framework and the Eu(3+) centers.
The loading of a metal‐organic framework (MOF), [Cu3(btc)2xH2O] HKUST‐1, with europium β‐diketonate complexes is studied with the goal to using the porous molecular framework as a photonic antenna. Whereas loading of HKUST‐1 powder particles produced via the conventional solvothermal synthesis method was strongly hindered, for HKUST‐1 SURMOFs, thin MOF films fabricated using the liquid phase epitaxy method, a high filling factor can be achieved. The optical properties of the HKUST‐1‐MOFs before and after loading were analysed with the aid of luminescence spectroscopy. Careful analysis of the absorption spectra reveals the presence of an effective energy transfer between the HKUST‐1 framework and the Eu3+ centers. The optical properties of HKUST‐1 MOFs before and after loading a Eu3+ complex are analysed with the aid of luminescence spectroscopy (see graphic). The presence of an effective energy transfer between the HKUST‐1 framework and the Eu3+ centers was found as is described herein.
Author Arslan, Hasan Kemal
Ladnorg, Tatjana
Shekhah, Osama
Adlung, Matthias
Franzreb, Matthias
Stammer, Xia
Gliemann, Hartmut
Wöll, Christof
Zybaylo, Olexandra
Wickleder, Claudia
Streit, Huayna Cerqueira
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  givenname: Olexandra
  surname: Zybaylo
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  givenname: Tatjana
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  givenname: Claudia
  surname: Wickleder
  fullname: Wickleder, Claudia
  email: wickleder@chemie.uni-siegen.de
  organization: Inorganic Chemistry, Science and Engineering, University of Siegen, Adolf-Reichwein-Straße 2, 57076 Siegen (Germany)
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Issue 11
Keywords Metal organic framework
photonic antenna
europium complexes
Rare earth metal complex
Luminescence
Organic ligand
Europium complex
Energy transfer
surface-anchored metalorganic frameworks
Language English
License CC BY 4.0
Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.
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Snippet The loading of a metal‐organic framework (MOF), [Cu3(btc)2xH2O] HKUST‐1, with europium β‐diketonate complexes is studied with the goal to using the porous...
The loading of a metal-organic framework (MOF), [Cu(3)(btc)(2)xH(2)O] HKUST-1, with europium β-diketonate complexes is studied with the goal to using the...
Abstract The loading of a metal‐organic framework (MOF), [Cu 3 (btc) 2 x H 2 O] HKUST‐1, with europium β‐diketonate complexes is studied with the goal to using...
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SubjectTerms Chemistry
energy transfer
europium complexes
Exact sciences and technology
General and physical chemistry
luminescence
photonic antennae
Surface physical chemistry
surface-anchored metal-organic frameworks
Title Surface-Anchored MOF-Based Photonic Antennae
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https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fcphc.201200262
https://www.ncbi.nlm.nih.gov/pubmed/22700363
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Volume 13
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