Properties of negative thermal expansion β -eucryptite ceramics prepared by spark plasma sintering

Abstract: β -eucryptite powders are prepared by the sol-gel method through using tetraethoxysilane lithium nitrate and aluminum isopropoxide as starting materials. β -eucryptite ceramics are prepared by spark plasma sintering. The effects of sintering temperature on the negative thermal expansion properties of the β -eucryptite are investigated by x-ray diffraction (XRD), scanning electron microscopy, and thermal expansion test. The XRD results exhibit no change in the crystal structure of the sample prepared by differe… Show more

“…At present, there are many kinds of NTE materials, and the common ones mainly include various framework oxides, zeolites, cyanides, anti-perovskite nitrides and metal–organic frameworks. 29–31 A typical one is ZrW 2 O 8 ; however, despite its good NTE properties, it is metastable below 777 °C and decomposes into ZrO 2 and WO 3 in the temperature range of 777 to 1105 °C, which is not suitable for carbonation. 32…”

Long-stable solar energy capture and storage via negative thermal expansion regulated calcium-based particles

“…At present, there are many kinds of NTE materials, and the common ones mainly include various framework oxides, zeolites, cyanides, anti-perovskite nitrides and metal–organic frameworks. 29–31 A typical one is ZrW 2 O 8 ; however, despite its good NTE properties, it is metastable below 777 °C and decomposes into ZrO 2 and WO 3 in the temperature range of 777 to 1105 °C, which is not suitable for carbonation. 32…”

Long-stable solar energy capture and storage via negative thermal expansion regulated calcium-based particles

Negative Thermal Expansion of (ZrMg)xY2–2xMo3O12 Ceramics with Low Hygroscopicity

The Effect of Temperature on Synthetic Nano β-Eucryptite and Alumina Ceramic Materials: Thermal Expansion, Mechanical, and Physical Properties