Order-disorder phase transitions in Au-Cu nanocubes: From nano-thermodynamics to synthesis

R. Mendoza-Cruz; L. Bazán-Diaz; J. J. Velázquez-Salazar; J. E. Samaniego-Benitez; F. M. Ascencio-Aguirre; R. Herrera-Becerra; M. José-Yacamán; G. Guisbiers

doi:10.1039/c7nr00028f

Order-disorder phase transitions in Au-Cu nanocubes: From nano-thermodynamics to synthesis

R. Mendoza-Cruz, L. Bazán-Diaz, J. J. Velázquez-Salazar, J. E. Samaniego-Benitez, F. M. Ascencio-Aguirre, R. Herrera-Becerra, M. José-Yacamán, G. Guisbiers

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

30 Citas (Scopus)

Resumen

Catalysts have been widely used in industries and can be optimized by tuning the composition and chemical ordering of the elements involved in the nano-alloy. Among bi-metallic alloys, the Au-Cu system is of particular interest because it exhibits ordered phases at low temperatures. Nevertheless, the temperature at which these ordered structures are formed is totally unknown at the nanoscale. Consequently, to speed up the development of these catalysts, this paper theoretically predicts the structural phase transitions between ordered and disordered phases for the Au-Cu system by using nano-thermodynamics. Following the predictions, the suggested annealing temperatures have been carefully chosen and consequently, Au-Cu ordered nanocubes have been successfully synthesized through a solventless protocol. The results are fully supported by electron microscopy observations.

Idioma original	Inglés
Páginas (desde-hasta)	9267-9274
Número de páginas	8
Publicación	Nanoscale
Volumen	9
N.º	27
DOI	https://doi.org/10.1039/c7nr00028f
Estado	Publicada - 21 jul. 2017
Publicado de forma externa	Sí

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abstract = "Catalysts have been widely used in industries and can be optimized by tuning the composition and chemical ordering of the elements involved in the nano-alloy. Among bi-metallic alloys, the Au-Cu system is of particular interest because it exhibits ordered phases at low temperatures. Nevertheless, the temperature at which these ordered structures are formed is totally unknown at the nanoscale. Consequently, to speed up the development of these catalysts, this paper theoretically predicts the structural phase transitions between ordered and disordered phases for the Au-Cu system by using nano-thermodynamics. Following the predictions, the suggested annealing temperatures have been carefully chosen and consequently, Au-Cu ordered nanocubes have been successfully synthesized through a solventless protocol. The results are fully supported by electron microscopy observations.",

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AU - Mendoza-Cruz, R.

AU - Bazán-Diaz, L.

AU - Velázquez-Salazar, J. J.

AU - Samaniego-Benitez, J. E.

AU - Ascencio-Aguirre, F. M.

AU - Herrera-Becerra, R.

AU - José-Yacamán, M.

AU - Guisbiers, G.

PY - 2017/7/21

Y1 - 2017/7/21

N2 - Catalysts have been widely used in industries and can be optimized by tuning the composition and chemical ordering of the elements involved in the nano-alloy. Among bi-metallic alloys, the Au-Cu system is of particular interest because it exhibits ordered phases at low temperatures. Nevertheless, the temperature at which these ordered structures are formed is totally unknown at the nanoscale. Consequently, to speed up the development of these catalysts, this paper theoretically predicts the structural phase transitions between ordered and disordered phases for the Au-Cu system by using nano-thermodynamics. Following the predictions, the suggested annealing temperatures have been carefully chosen and consequently, Au-Cu ordered nanocubes have been successfully synthesized through a solventless protocol. The results are fully supported by electron microscopy observations.

AB - Catalysts have been widely used in industries and can be optimized by tuning the composition and chemical ordering of the elements involved in the nano-alloy. Among bi-metallic alloys, the Au-Cu system is of particular interest because it exhibits ordered phases at low temperatures. Nevertheless, the temperature at which these ordered structures are formed is totally unknown at the nanoscale. Consequently, to speed up the development of these catalysts, this paper theoretically predicts the structural phase transitions between ordered and disordered phases for the Au-Cu system by using nano-thermodynamics. Following the predictions, the suggested annealing temperatures have been carefully chosen and consequently, Au-Cu ordered nanocubes have been successfully synthesized through a solventless protocol. The results are fully supported by electron microscopy observations.

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Order-disorder phase transitions in Au-Cu nanocubes: From nano-thermodynamics to synthesis

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