Sulfur as a side product of natural gas and oil refining is an underused resource. Converting landfilled sulfur waste into materials merges the ecological imperative of resource efficiency with economic considerations. A strategy to convert sulfur into polymeric materials is the inverse vulcanization reaction of sulfur with alkenes. However, the materials formed are of limited applicability, because they need to be cured at high temperatures (>130 °C) for many hours. Herein, we report the reaction of elemental sulfur with styrylethyltrimethoxysilane. Marrying the inverse vulcanization and silane chemistry yielded high sulfur content polysilanes, which could be cured via room temperature polycondensation to obtain coated surfaces, particles, and crosslinked materials. The polycondensation was triggered by hydrolysis of poly(sulfur-r-styrylethyltrimethoxysilane) (poly(S -r-StyTMS) under mild conditions (HCl, pH 4). For the first time, an inverse vulcanization polymer could be conveniently coated and mildly cured via post-polycondensation. Silica microparticles coated with the high sulfur content polymer could improve their Hg ion remediation capability.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7589442 | PMC |
| http://dx.doi.org/10.1002/anie.202006522 | DOI Listing |
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Article Synopsis
- Researchers developed a new type of infrared (IR) transparent polymer using inverse vulcanization with a high boiling point compound (DMMD) and sulfur, aiming to overcome the limitations of traditional organic materials in IR optics.
- The resulting polymer (Poly (S-r-DMMD)) showcases adjustable thermal properties (with a temperature range of 98.3-119.8 °C) and good IR transmittance (ranging from 1.5-52.6% for different IR regions), making it a suitable alternative to inorganic materials.
- Additionally, this polymer can be easily shaped into large Fresnel lenses for IR imaging, offering potential applications in optical device production while enhancing the understanding of achieving a
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