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源自新型聚烷氧基倍半硅氮烷的非晶态氮氧化硅的微孔性及二氧化碳捕获性能

Microporosity and CO₂ Capture Properties of Amorphous Silicon Oxynitride Derived from Novel Polyalkoxysilsesquiazanes.

作者信息

Iwase Yoshiaki, Horie Yoji, Honda Sawao, Daiko Yusuke, Iwamoto Yuji

机构信息

Applied Research Laboratory, General Center of Research and Development, Toagosei Co., Ltd., 8, Showa-cho, Minato-ku, Nagoya 455-0026, Japan.

Department of Life Science and Applied Chemistry, Graduate School of Engineering, Nagoya Institute of Technology, Gokiso-cho, Showa-ku, Nagoya 466-8555, Japan.

出版信息

Materials (Basel). 2018 Mar 13;11(3):422. doi: 10.3390/ma11030422.

DOI:10.3390/ma11030422
PMID:29534056
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5873001/
Abstract

Polyalkoxysilsesquiazanes ([ROSi(NH)], ROSZ, R = Et, nPr, iPr, nBu, sBu, nHex, sHex, cHex, decahydronaphthyl (DHNp)) were synthesized by ammonolysis at -78 °C of alkoxytrichlorosilane (ROSiCl₃), which was isolated by distillation as a reaction product of SiCl₄ and ROH. The simultaneous thermogravimetric and mass spectrometry analyses of the ROSZs under helium revealed a common decomposition reaction, the cleavage of the oxygen-carbon bond of the RO group to evolve alkene as a main gaseous species formed in-situ, leading to the formation of microporous amorphous Si-O-N at 550 °C to 800 °C. The microporosity in terms of the peak of the pore size distribution curve located within the micropore size range (<2 nm) and the total micropore volume, as well as the specific surface area (SSA) of the Si-O-N, increased consistently with the molecular size estimated for the alkene formed in-situ during the pyrolysis. The CO₂ capture capacity at 0 °C of the Si-O-N material increased consistently with its SSA, and an excellent CO₂ capture capacity of 3.9 mmol·g at 0 °C and CO₂ 1 atm was achieved for the Si-O-N derived from DHNpOSZ having an SSA of 750 m²·g. The CO₂ capture properties were further discussed based on their temperature dependency, and a surface functional group of the Si-O-N formed in-situ during the polymer/ceramics thermal conversion.

摘要

聚烷氧基倍半硅氮烷([ROSi(NH)],ROSZ,R = 乙基、正丙基、异丙基、正丁基、仲丁基、正己基、仲己基、环己基、十氢萘基(DHNp))是通过在-78°C下对烷氧基三氯硅烷(ROSiCl₃)进行氨解反应合成的,该烷氧基三氯硅烷是通过蒸馏从SiCl₄和ROH的反应产物中分离出来的。在氦气气氛下对ROSZ进行同步热重分析和质谱分析,揭示了一个共同的分解反应,即RO基团的氧-碳键断裂,以原位形成烯烃作为主要气态产物,从而在550°C至800°C形成微孔无定形Si-O-N。根据位于微孔尺寸范围内(<2 nm)的孔径分布曲线峰值、总微孔体积以及Si-O-N的比表面积(SSA)来衡量的微孔率,与热解过程中原位形成的烯烃的分子尺寸一致增加。Si-O-N材料在0°C时的CO₂捕获容量随其SSA一致增加,对于具有750 m²·g SSA的由DHNpOSZ衍生的Si-O-N,在0°C和1 atm CO₂条件下实现了3.9 mmol·g的优异CO₂捕获容量。基于其温度依赖性进一步讨论了CO₂捕获性能,以及在聚合物/陶瓷热转化过程中原位形成的Si-O-N的表面官能团。

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