CarbonSilvanus advances a portfolio of six IP-protected innovation platforms that bridge advanced carbon materials, intelligent manufacturing, and infrastructure-scale applications.
These platforms define our current fields of research and proposal development, where ongoing collaborations and initiatives aim to translate emerging science into practical engineering solutions.
Design of biochar-based filtration media for wastewater treatment and environmental remediation. The Carbon-Water ™ concept investigates adsorption and ion-exchange mechanisms for sodium and chloride removal in agricultural and municipal water systems.
Development of carbon-smart concrete composites using carbonated biochar to partially replace cement and fine aggregate. A demonstration sidewalk project utilizing CarbonSmart-CEM™ was successfully completed in Bellingham, WA, with support from Washington State University, the City of Bellingham, and the Washington State Department of Commerce.
The DOE SBIR-funded CarbonSmart-LWA™ research focuses on optimizing mix design, strength-to-density ratio, and thermal and acoustic insulation performance of artificial lightweight aggregates for pilot-scale validation.
One-part and ready-mix GeoOne™ geopolymer binder systems designed for durable, low-emission concrete alternatives, with research focusing on formulation optimization, activator chemistry, and scale-up feasibility.
Integration of engineered biochar and nanocarbon additives into asphalt binders enhances durability, lowers VOC emissions, and improves interfacial bonding. Laboratory studies confirm promising rheological stability and emission-control potential.
Application of digital twins and AI-driven analytics (CarbonTwin™) to monitor process variability, enable predictive quality control, and support data-centric materials design — including Carbon-Water™, CarbonSmart-CEM™, CarbonSmart-LWA™, GeoOne™, and other manufacturing processes.
Holistic framework for converting industrial and agricultural residues into functional carbon materials. This research integrates Life-Cycle Assessment (LCA), Techno-Economic Analysis (TEA), and Life-Cycle Cost Analysis (LCCA) to evaluate sustainability, scalability, and environmental benefits of circular manufacturing pathways.
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