High-Temperature Resistant Polyborosilazanes with Tailored Structures

High-Temperature Resistant Polyborosilazanes with Tailored Structures

Boron-containing organosilicon polymers are widely used under harsh environments as preceramic polymers for advanced ceramics fabrication. However, harmful chemicals released during synthesis and the complex synthesis routes have limited their applications. To solve the problems, a two-component rou...

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Bibliographic Details
Published in:Polymers Vol. 13; no. 3; p. 467
Main Authors: Wang, Bijie, Chen, Ke, Li, Tianhao, Sun, Xun, Liu, Ming, Yang, Lingwei, Hu, Xiao Matthew, Xu, Jian, He, Liu, Huang, Qing, Jiang, Linbin, Song, Yujie
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 01-02-2021
MDPI
Subjects:
Argon
Binding sites
Boron
By products
Contact angle
Enthalpy
Fire hazards
Heat resistance
High temperature
Mechanical properties
Molecular structure
Nitrogen
Polymers
Polysilazane
Silicon
Spectrum analysis
Thermal stability
United States > US
China
Germany
polyborosilazane
high temperature resistant
boron-containing polymer
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Summary:Boron-containing organosilicon polymers are widely used under harsh environments as preceramic polymers for advanced ceramics fabrication. However, harmful chemicals released during synthesis and the complex synthesis routes have limited their applications. To solve the problems, a two-component route was adopted to synthesize cross-linked boron-containing silicone polymer (CPBCS) via a solventless process. The boron content and CPBCSs' polymeric structures could be readily tuned through controlling the ratio of multifunctional boron hybrid silazane monomers (BSZ12) and poly[imino(methylsilylene)]. The CPBCSs showed high thermal stability and good mechanical properties. The CPBCS with Si-H/C=C ratio of 10:1 showed 75 wt% char yields at 1000 °C in argon, and the heat release capacity (HRC) and total heat release (THR) are determined to be 37.9 J/g K and 6.2 KJ/g, demonstrating high thermal stability and flame retardancy. The reduced modulus and hardness of CPBCS are 0.30 GPa and 2.32 GPa, respectively. The novel polysilazanes can be potentially used under harsh environments, such as high temperatures or fire hazards.
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ISSN:2073-4360
2073-4360
DOI:10.3390/polym13030467