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Low Temperature Synthesis and Characterization of AlScMo(3)O(12)

Recent interest in low and negative thermal expansion materials has led to significant research on compounds that exhibit this property, much of which has targeted the A(2)M(3)O(12) family (A = trivalent cation, M = Mo, W). The expansion and phase transition behavior in this family can be tuned thro...

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Autores principales: Truitt, Rebecca, Hermes, Ilka, Main, Alyssa, Sendecki, Anne, Lind, Cora
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2015
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5455278/
https://www.ncbi.nlm.nih.gov/pubmed/28787966
http://dx.doi.org/10.3390/ma8020700
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author Truitt, Rebecca
Hermes, Ilka
Main, Alyssa
Sendecki, Anne
Lind, Cora
author_facet Truitt, Rebecca
Hermes, Ilka
Main, Alyssa
Sendecki, Anne
Lind, Cora
author_sort Truitt, Rebecca
collection PubMed
description Recent interest in low and negative thermal expansion materials has led to significant research on compounds that exhibit this property, much of which has targeted the A(2)M(3)O(12) family (A = trivalent cation, M = Mo, W). The expansion and phase transition behavior in this family can be tuned through the choice of the metals incorporated into the structure. An undesired phase transition to a monoclinic structure with large positive expansion can be suppressed in some solid solutions by substituting the A-site by a mixture of two cations. One such material, AlScMo(3)O(12), was successfully synthesized using non-hydrolytic sol-gel chemistry. Depending on the reaction conditions, phase separation into Al(2)Mo(3)O(12) and Sc(2)Mo(3)O(12) or single-phase AlScMo(3)O(12) could be obtained. Optimized conditions for the reproducible synthesis of stoichiometric, homogeneous AlScMo(3)O(12) were established. High resolution synchrotron diffraction experiments were carried out to confirm whether samples were homogeneous and to estimate the Al:Sc ratio through Rietveld refinement and Vegard’s law. Single-phase samples were found to adopt the orthorhombic Sc(2)W(3)O(12) structure at 100 to 460 K. In contrast to all previously-reported A(2)M(3)O(12) compositions, AlScMo(3)O(12) exhibited positive thermal expansion along all unit cell axes instead of contraction along one or two axes, with expansion coefficients (200–460 K) of α(a) = 1.7 × 10(−6) K(−1), α(b) = 6.2 × 10(−6) K(−1), α(c) = 2.9 × 10(−6) K(−1) and α(V) = 10.8 × 10(−6) K(−1), respectively.
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spelling pubmed-54552782017-07-28 Low Temperature Synthesis and Characterization of AlScMo(3)O(12) Truitt, Rebecca Hermes, Ilka Main, Alyssa Sendecki, Anne Lind, Cora Materials (Basel) Article Recent interest in low and negative thermal expansion materials has led to significant research on compounds that exhibit this property, much of which has targeted the A(2)M(3)O(12) family (A = trivalent cation, M = Mo, W). The expansion and phase transition behavior in this family can be tuned through the choice of the metals incorporated into the structure. An undesired phase transition to a monoclinic structure with large positive expansion can be suppressed in some solid solutions by substituting the A-site by a mixture of two cations. One such material, AlScMo(3)O(12), was successfully synthesized using non-hydrolytic sol-gel chemistry. Depending on the reaction conditions, phase separation into Al(2)Mo(3)O(12) and Sc(2)Mo(3)O(12) or single-phase AlScMo(3)O(12) could be obtained. Optimized conditions for the reproducible synthesis of stoichiometric, homogeneous AlScMo(3)O(12) were established. High resolution synchrotron diffraction experiments were carried out to confirm whether samples were homogeneous and to estimate the Al:Sc ratio through Rietveld refinement and Vegard’s law. Single-phase samples were found to adopt the orthorhombic Sc(2)W(3)O(12) structure at 100 to 460 K. In contrast to all previously-reported A(2)M(3)O(12) compositions, AlScMo(3)O(12) exhibited positive thermal expansion along all unit cell axes instead of contraction along one or two axes, with expansion coefficients (200–460 K) of α(a) = 1.7 × 10(−6) K(−1), α(b) = 6.2 × 10(−6) K(−1), α(c) = 2.9 × 10(−6) K(−1) and α(V) = 10.8 × 10(−6) K(−1), respectively. MDPI 2015-02-16 /pmc/articles/PMC5455278/ /pubmed/28787966 http://dx.doi.org/10.3390/ma8020700 Text en © 2015 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Truitt, Rebecca
Hermes, Ilka
Main, Alyssa
Sendecki, Anne
Lind, Cora
Low Temperature Synthesis and Characterization of AlScMo(3)O(12)
title Low Temperature Synthesis and Characterization of AlScMo(3)O(12)
title_full Low Temperature Synthesis and Characterization of AlScMo(3)O(12)
title_fullStr Low Temperature Synthesis and Characterization of AlScMo(3)O(12)
title_full_unstemmed Low Temperature Synthesis and Characterization of AlScMo(3)O(12)
title_short Low Temperature Synthesis and Characterization of AlScMo(3)O(12)
title_sort low temperature synthesis and characterization of alscmo(3)o(12)
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5455278/
https://www.ncbi.nlm.nih.gov/pubmed/28787966
http://dx.doi.org/10.3390/ma8020700
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