Naphthalene-based periodic nanoporous organosilicas: I. Synthesis and structural characterization
Naphthalene-based periodic nanoporous organosilicas: I. Synthesis and structural characterization
Novel periodic nanoporous organosilicas (PNOs) were synthesized by direct co-condensation of tetraethylorthosilicate and of the prior synthesized compound triethoxy(naphthalen-1-yl)silane. Structural characterization of materials was performed with various techniques such as 1H and 13C nuclear magnetic resonance, X-ray powder diffraction, Fourier transform infrared spectroscopy, ultraviolet–visible and photoluminescence emission and excitation spectroscopy, differential thermal and thermo-gravimetric analyses, nitrogen porosimetry and helium pycnometry. Naphthalene-based moieties were grafted on the silicate matrix through oxygen bonds resulted to novel organosilicate final materials that exhibited high naphthalene content up to 17 wt.% with a corresponding 1.33 mmol/g molar concentration, high crystallinity, specific surface area larger than 1000 m2/g and pore size distributions in the microporous/mesoporous boundary. Optical properties have been found to be comparable to the naphthalene. The attachment of the optically active part to the mesopores walls and its specific tuning for blue/UV luminescence demonstrates that this type of the reported low cost materials can be considered as phosphors in UV Leds. Tuning by using the red shift of similar larger molecules, all simultaneously trapped within the PNO, may prove to be efficient white light phosphor. Moreover, the nonlinear active properties of the active naphthalene may also allow for novel applications. Finally, materials were studied for hydrogen and methane storage with Sieverts’ apparatus and demonstrated high H2 and CH4 weight proportions for PNOs materials at various temperatures up to 4.3 MPa and 3.5 MPa respectively as presented in part II.
324-331
Dimos, Konstantinos
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Antoniou, Myrsini K.
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Meichanetzoglou, Aimilia
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Lymperopoulou, Smaragda
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Ouzouni, Maria-Dimitra
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Koutselas, Ioannis B.
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Fokas, Demosthenes
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Karakassides, Michael A.
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Agostino, Raffaele G.
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Gournis, Dimitrios
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1 August 2012
Dimos, Konstantinos
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Antoniou, Myrsini K.
8fa908c6-8906-4e2d-9a1c-e443941c0d7d
Meichanetzoglou, Aimilia
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Lymperopoulou, Smaragda
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Ouzouni, Maria-Dimitra
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Koutselas, Ioannis B.
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Fokas, Demosthenes
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Karakassides, Michael A.
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Agostino, Raffaele G.
d1d14288-a785-4058-b042-e2b2d3a9fcf8
Gournis, Dimitrios
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Dimos, Konstantinos, Antoniou, Myrsini K., Meichanetzoglou, Aimilia, Lymperopoulou, Smaragda, Ouzouni, Maria-Dimitra, Koutselas, Ioannis B., Fokas, Demosthenes, Karakassides, Michael A., Agostino, Raffaele G. and Gournis, Dimitrios
(2012)
Naphthalene-based periodic nanoporous organosilicas: I. Synthesis and structural characterization.
Microporous and Mesoporous Materials, 158, .
(doi:10.1016/j.micromeso.2012.03.037).
Abstract
Novel periodic nanoporous organosilicas (PNOs) were synthesized by direct co-condensation of tetraethylorthosilicate and of the prior synthesized compound triethoxy(naphthalen-1-yl)silane. Structural characterization of materials was performed with various techniques such as 1H and 13C nuclear magnetic resonance, X-ray powder diffraction, Fourier transform infrared spectroscopy, ultraviolet–visible and photoluminescence emission and excitation spectroscopy, differential thermal and thermo-gravimetric analyses, nitrogen porosimetry and helium pycnometry. Naphthalene-based moieties were grafted on the silicate matrix through oxygen bonds resulted to novel organosilicate final materials that exhibited high naphthalene content up to 17 wt.% with a corresponding 1.33 mmol/g molar concentration, high crystallinity, specific surface area larger than 1000 m2/g and pore size distributions in the microporous/mesoporous boundary. Optical properties have been found to be comparable to the naphthalene. The attachment of the optically active part to the mesopores walls and its specific tuning for blue/UV luminescence demonstrates that this type of the reported low cost materials can be considered as phosphors in UV Leds. Tuning by using the red shift of similar larger molecules, all simultaneously trapped within the PNO, may prove to be efficient white light phosphor. Moreover, the nonlinear active properties of the active naphthalene may also allow for novel applications. Finally, materials were studied for hydrogen and methane storage with Sieverts’ apparatus and demonstrated high H2 and CH4 weight proportions for PNOs materials at various temperatures up to 4.3 MPa and 3.5 MPa respectively as presented in part II.
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Accepted/In Press date: 27 March 2012
Published date: 1 August 2012
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Organic Chemistry: SCF
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Local EPrints ID: 403239
URI: http://eprints.soton.ac.uk/id/eprint/403239
PURE UUID: 8e2bd49e-e828-455f-9657-c462f28600f0
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Date deposited: 02 Dec 2016 13:58
Last modified: 15 Mar 2024 03:37
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Author:
Konstantinos Dimos
Author:
Myrsini K. Antoniou
Author:
Aimilia Meichanetzoglou
Author:
Smaragda Lymperopoulou
Author:
Maria-Dimitra Ouzouni
Author:
Ioannis B. Koutselas
Author:
Demosthenes Fokas
Author:
Michael A. Karakassides
Author:
Raffaele G. Agostino
Author:
Dimitrios Gournis
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