1. Investigations on the intrinsic and template-dependent transformations of AlPO4-11 molecular sieve under high pressure.
- Author
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Chen, Shuanglong, Li, Xin, Yao, Zhen, Dong, Enlai, Shi, Lifen, Du, Mingrun, Yang, Xibao, Liu, Ran, Lv, Hang, and Liu, Bingbing
- Subjects
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MOLECULAR sieves , *X-ray powder diffraction , *AMORPHIZATION , *INFRARED spectroscopy , *INFRARED spectra , *ELECTRORHEOLOGY - Abstract
In this study, aluminophosphate molecular sieve AlPO 4 -11, with one-dimensional elliptical channels, was investigated under high pressure in non-penetrating silicone oil by X-ray powder diffraction, infrared spectroscopy and theoretical simulation, focusing on its intrinsic and template-modified mechanical behaviors. Two distinct compressible regimes were observed for both the calcined and as-synthesized AlPO 4 -11 frameworks before pressure-induced amorphization (PIA). The channel cross-section in the calcined AlPO 4 -11 framework showed an obvious increase in the ellipticity during this process. The framework structure began to lose crystallinity at approximately 2–3 GPa and underwent significant amorphization at 6.6 GPa. PIA was mainly induced via the destruction of the constructed species along the periodic crystallographic planes which are parallel to the channel axis. The bulk moduli showed that this empty framework was rather soft in these regimes. For the as-synthesized AlPO 4 -11 framework, the mechanical stability of the channels was markedly improved by the template molecules. A different elliptic deformation of the cross-section with a reduced contractility in the minor axis direction was presented. Discontinuous volume evolution occurs at 3–4 GPa and significant amorphization was postponed to 13.7 GPa. The as-synthesized AlPO 4 -11 was stiffer than calcined AlPO 4 -11 and showed a soft to hard transformation due to the strengthened host-guest interaction upon compression. Moreover, infrared spectra indirectly confirmed the structural collapses by detecting the vibrational characteristics of the embedded template molecules. The present results provided a comparative and basic knowledge of the intrinsic and extrinsic stability, compressibility, channel deformation and collapse of the AlPO 4 -11 framework under high pressure. This study emphasized the importance of guest molecules in modifying the mechanical behaviors of zeolites and resisting framework collapse. • Both the calcined and as-synthesized AlPO 4 -11 frameworks exhibit isostructural transformations under high pressure. • Two different compressible regimes are found before pressure-induced amorphization. • The template molecules strengthen the mechanical stability and modify the structural evolution of AlPO 4 -11. • The template molecules also function as local probes to detect the framework transformations in the infrared experiment. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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