Journal
JOURNAL OF THE EUROPEAN CERAMIC SOCIETY
Volume 41, Issue 13, Pages 6366-6376Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.jeurceramsoc.2021.05.046
Keywords
Preceramic polymer; Polymer-derived ceramics; Bioinspired; SiC; TiC
Categories
Funding
- Air Force Research Laboratory Materials and Manufacturing Directorate
- Air Force Office of Scientific Research
- AFRL/RX [FA865015D5230]
- Air Force Research Laboratory
- AFRL/RX Lab Director's Fund
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Metal coordination chemistry is commonly used in biology and materials science to fine-tune material properties. This study demonstrates the control of material characteristics through metal ion coordination cross-linking in polymers, showing its significance in enhancing material performance.
Metal coordination chemistry is common in biology, with many proteins containing metal ion-based structural motifs or catalytic centers. An interesting example of nature's use of coordinate bonding to create a proteinaceous structural material is found in the Alitta virens marine worm jaw. Inspired by Zn+2 cross-linked polymers in A. virens, we have extended coordination cross-linking to preceramic polymers. Commercially available Si-based backbones functionalized with pyridyl-moieties were introduced to metal ions to initiate cross-linking. Metal coordination offered a single knob to tune multiple characteristics of the material before and after pyrolysis. The loading of the metal ions into the polymer impacted the viscoelastic properties, thermal stability, and ceramic yield. Pyrolysis yielded a ceramic representative of the metal ion cross-linker (e.g., forming TiC/SiC nanocomposites).
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