High surface area of carbonaceous Cr2GaC composite microspheres synthesized by sol-gel chemistry

Jordan Sinclair; Jan P. Siebert; Matt Flores; David Ciota; Dong Kyun Seo; Christina S. Birkel

doi:10.1039/d4nj02038c

High surface area of carbonaceous Cr₂GaC composite microspheres synthesized by sol-gel chemistry

Jordan Sinclair, Jan P. Siebert, Matt Flores, David Ciota, Dong Kyun Seo, Christina S. Birkel

Molecular Sciences, School of (SMS)

Research output: Contribution to journal › Article › peer-review

Abstract

MAX phases are widely renowned for incorporating metallic and ceramic properties into a single compound but lack high degrees of porosity. Using a sol-gel chemistry technique, known as a polymer type II complex method, more flexibility of the shape, morphology, microstructure, and porosity is achieved while simultaneously synthesizing the MAX phase. This sol-gel chemistry technique demonstrates a signficant departure from traditional solid state synthetic methods. Temperature profiles in this study allowed insights into the influence of furnace and microwave heating on the resulting products. The carbonaceous Cr₂GaC spheres were identified to exhibit type IV isotherm behavior and a hysteresis type of H2(a).

Original language	English (US)
Pages (from-to)	11122-11128
Number of pages	7
Journal	New Journal of Chemistry
Volume	48
Issue number	24
DOIs	https://doi.org/10.1039/d4nj02038c
State	Published - May 30 2024

ASJC Scopus subject areas

Catalysis
General Chemistry
Materials Chemistry

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abstract = "MAX phases are widely renowned for incorporating metallic and ceramic properties into a single compound but lack high degrees of porosity. Using a sol-gel chemistry technique, known as a polymer type II complex method, more flexibility of the shape, morphology, microstructure, and porosity is achieved while simultaneously synthesizing the MAX phase. This sol-gel chemistry technique demonstrates a signficant departure from traditional solid state synthetic methods. Temperature profiles in this study allowed insights into the influence of furnace and microwave heating on the resulting products. The carbonaceous Cr2GaC spheres were identified to exhibit type IV isotherm behavior and a hysteresis type of H2(a).",

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AU - Siebert, Jan P.

AU - Flores, Matt

AU - Ciota, David

AU - Seo, Dong Kyun

AU - Birkel, Christina S.

PY - 2024/5/30

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N2 - MAX phases are widely renowned for incorporating metallic and ceramic properties into a single compound but lack high degrees of porosity. Using a sol-gel chemistry technique, known as a polymer type II complex method, more flexibility of the shape, morphology, microstructure, and porosity is achieved while simultaneously synthesizing the MAX phase. This sol-gel chemistry technique demonstrates a signficant departure from traditional solid state synthetic methods. Temperature profiles in this study allowed insights into the influence of furnace and microwave heating on the resulting products. The carbonaceous Cr2GaC spheres were identified to exhibit type IV isotherm behavior and a hysteresis type of H2(a).

AB - MAX phases are widely renowned for incorporating metallic and ceramic properties into a single compound but lack high degrees of porosity. Using a sol-gel chemistry technique, known as a polymer type II complex method, more flexibility of the shape, morphology, microstructure, and porosity is achieved while simultaneously synthesizing the MAX phase. This sol-gel chemistry technique demonstrates a signficant departure from traditional solid state synthetic methods. Temperature profiles in this study allowed insights into the influence of furnace and microwave heating on the resulting products. The carbonaceous Cr2GaC spheres were identified to exhibit type IV isotherm behavior and a hysteresis type of H2(a).

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High surface area of carbonaceous Cr₂GaC composite microspheres synthesized by sol-gel chemistry

Abstract

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