Barium boron aluminum silicate glass system for solid state optical gas sensors

Detalhes bibliográficos
Autor(a) principal: SILVA, M.J. da
Data de Publicação: 2017
Outros Autores: KARCZEWSKI, J., JASINSKI, P., CHRZAN, A., KALINOWSKI, P., SZYMCZEWSKA, D., JASINSKI, G., INTERNATIONAL CONFERENCE ON OPTICAL AND ELECTRONIC SENSORS, 14th
Tipo de documento: Artigo de conferência
Título da fonte: Repositório Institucional do IPEN
Texto Completo: http://repositorio.ipen.br/handle/123456789/27571
Resumo: Recent increasing demand for new eco-friendly materials and for low cost fabrication process for use in optical sensors field, raise concern about alternative materials for this application. We have designed two glass-ceramics compositions from the quaternary ROAl2O3- SiO2-B2O3(R=Ba) alkali-earth aluminum silicate system, labeled B72 and B69, with high refractive index (>1.6), large values of Abbe number (94.0 and 53.0, respectively), and free of lead and arsenic. We present an analysis and discussion of experimental optical properties, thermal and thermo-chemical stability along with important properties such as transition temperature (Tg), onset of crystallization (Tx) as well transport properties as ionic conductivity behavior in the quaternary glass-ceramic system containing boron for use as optical sensors. Complex Impedance Spectra (Bode Plot) and Potentiodynamic Polarization curves (Tafel plots) measurements were carried out in the temperature range of 600 to 850??C. The most probable conductivity mechanism is a thermally activated process of mobile ions overcoming a potential barrier (EA), according to the Arrhenius regime. Here we report that charge transfer is caused by the flux of electrons, in the region of elevated temperatures (>700??C), and is affected by immiscibility of crystals, nucleation and growth type, that causes phase separation. We found conductivity (??) values from 10-9 to 10-5 S/cm at temperatures between 700 and 850??C. Our results highlight a need for research on ion mobility in the glassy network above the transition range, and the effect cause by metastable immiscibility in the alkaline-earth glasses are exposed. The two glass compositions B72 and B69 can be tailored by proper use as glassy optical sensor.
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spelling JASINSKI, PIOTRSILVA, M.J. daKARCZEWSKI, J.JASINSKI, P.CHRZAN, A.KALINOWSKI, P.SZYMCZEWSKA, D.JASINSKI, G.INTERNATIONAL CONFERENCE ON OPTICAL AND ELECTRONIC SENSORS, 14th2017-06-05T11:53:54Z2017-06-05T11:53:54ZJune 19, 2016http://repositorio.ipen.br/handle/123456789/27571Recent increasing demand for new eco-friendly materials and for low cost fabrication process for use in optical sensors field, raise concern about alternative materials for this application. We have designed two glass-ceramics compositions from the quaternary ROAl2O3- SiO2-B2O3(R=Ba) alkali-earth aluminum silicate system, labeled B72 and B69, with high refractive index (>1.6), large values of Abbe number (94.0 and 53.0, respectively), and free of lead and arsenic. We present an analysis and discussion of experimental optical properties, thermal and thermo-chemical stability along with important properties such as transition temperature (Tg), onset of crystallization (Tx) as well transport properties as ionic conductivity behavior in the quaternary glass-ceramic system containing boron for use as optical sensors. Complex Impedance Spectra (Bode Plot) and Potentiodynamic Polarization curves (Tafel plots) measurements were carried out in the temperature range of 600 to 850??C. The most probable conductivity mechanism is a thermally activated process of mobile ions overcoming a potential barrier (EA), according to the Arrhenius regime. Here we report that charge transfer is caused by the flux of electrons, in the region of elevated temperatures (>700??C), and is affected by immiscibility of crystals, nucleation and growth type, that causes phase separation. We found conductivity (??) values from 10-9 to 10-5 S/cm at temperatures between 700 and 850??C. Our results highlight a need for research on ion mobility in the glassy network above the transition range, and the effect cause by metastable immiscibility in the alkaline-earth glasses are exposed. The two glass compositions B72 and B69 can be tailored by proper use as glassy optical sensor.Submitted by Marco Antonio Oliveira da Silva (maosilva@ipen.br) on 2017-06-05T11:53:54Z No. of bitstreams: 1 23814.pdf: 243095 bytes, checksum: 39c419d1655151a10d2b9c78c48508e3 (MD5)Made available in DSpace on 2017-06-05T11:53:54Z (GMT). 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dc.title.pt_BR.fl_str_mv Barium boron aluminum silicate glass system for solid state optical gas sensors
title Barium boron aluminum silicate glass system for solid state optical gas sensors
spellingShingle Barium boron aluminum silicate glass system for solid state optical gas sensors
SILVA, M.J. da
title_short Barium boron aluminum silicate glass system for solid state optical gas sensors
title_full Barium boron aluminum silicate glass system for solid state optical gas sensors
title_fullStr Barium boron aluminum silicate glass system for solid state optical gas sensors
title_full_unstemmed Barium boron aluminum silicate glass system for solid state optical gas sensors
title_sort Barium boron aluminum silicate glass system for solid state optical gas sensors
author SILVA, M.J. da
author_facet SILVA, M.J. da
KARCZEWSKI, J.
JASINSKI, P.
CHRZAN, A.
KALINOWSKI, P.
SZYMCZEWSKA, D.
JASINSKI, G.
INTERNATIONAL CONFERENCE ON OPTICAL AND ELECTRONIC SENSORS, 14th
author_role author
author2 KARCZEWSKI, J.
JASINSKI, P.
CHRZAN, A.
KALINOWSKI, P.
SZYMCZEWSKA, D.
JASINSKI, G.
INTERNATIONAL CONFERENCE ON OPTICAL AND ELECTRONIC SENSORS, 14th
author2_role author
author
author
author
author
author
author
dc.contributor.editor.none.fl_str_mv JASINSKI, PIOTR
dc.contributor.author.fl_str_mv SILVA, M.J. da
KARCZEWSKI, J.
JASINSKI, P.
CHRZAN, A.
KALINOWSKI, P.
SZYMCZEWSKA, D.
JASINSKI, G.
INTERNATIONAL CONFERENCE ON OPTICAL AND ELECTRONIC SENSORS, 14th
description Recent increasing demand for new eco-friendly materials and for low cost fabrication process for use in optical sensors field, raise concern about alternative materials for this application. We have designed two glass-ceramics compositions from the quaternary ROAl2O3- SiO2-B2O3(R=Ba) alkali-earth aluminum silicate system, labeled B72 and B69, with high refractive index (>1.6), large values of Abbe number (94.0 and 53.0, respectively), and free of lead and arsenic. We present an analysis and discussion of experimental optical properties, thermal and thermo-chemical stability along with important properties such as transition temperature (Tg), onset of crystallization (Tx) as well transport properties as ionic conductivity behavior in the quaternary glass-ceramic system containing boron for use as optical sensors. Complex Impedance Spectra (Bode Plot) and Potentiodynamic Polarization curves (Tafel plots) measurements were carried out in the temperature range of 600 to 850??C. The most probable conductivity mechanism is a thermally activated process of mobile ions overcoming a potential barrier (EA), according to the Arrhenius regime. Here we report that charge transfer is caused by the flux of electrons, in the region of elevated temperatures (>700??C), and is affected by immiscibility of crystals, nucleation and growth type, that causes phase separation. We found conductivity (??) values from 10-9 to 10-5 S/cm at temperatures between 700 and 850??C. Our results highlight a need for research on ion mobility in the glassy network above the transition range, and the effect cause by metastable immiscibility in the alkaline-earth glasses are exposed. The two glass compositions B72 and B69 can be tailored by proper use as glassy optical sensor.
publishDate 2017
dc.date.evento.pt_BR.fl_str_mv June 19, 2016
dc.date.accessioned.fl_str_mv 2017-06-05T11:53:54Z
dc.date.available.fl_str_mv 2017-06-05T11:53:54Z
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dc.relation.ispartofseries.pt_BR.fl_str_mv SPIE Proceedings Series, 10161
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