1414 Degrees Secures Exclusive Licence for Breakthrough Silicon Nanoparticle Battery Tech
1414 Degrees has acquired exclusive global rights to a patented silicon nanoparticle technology from George Washington University, aiming to revolutionize lithium-ion battery anodes with higher capacity and faster charging. The company also raised $1.214 million to accelerate commercialisation and OEM engagement starting late 2025.
- Exclusive global licence for patented SiNTL silicon nanoparticle technology
- Technology offers ~10× higher capacity than graphite anodes with faster charging
- Low-temperature, scalable, and environmentally friendly synthesis process
- $1.214 million placement secured to fund development and commercialisation
- Commercial engagement with OEMs targeted from Q4 2025
Strategic Acquisition Expands Battery Materials Portfolio
1414 Degrees Ltd (ASX – 14D) has taken a significant step into the lithium-ion battery sector by securing an exclusive worldwide licence for a novel silicon nanoparticle technology (SiNTL) developed by George Washington University. This patented technology promises to address long-standing challenges in silicon anodes, potentially delivering batteries with much higher energy density, faster charging times, and longer cycle life.
The SiNTL technology features an innovative low-temperature synthesis process that coats silicon nanoparticles with aluminium in a single step, enhancing conductivity and stability while avoiding hazardous chemicals. This scalable and cost-effective method aligns well with existing anode manufacturing lines, offering a practical pathway to commercialisation.
Market Opportunity and Commercialisation Pathway
The global silicon anode battery market is poised for explosive growth, forecast to expand from USD $536.5 million in 2025 to over $20 billion by 2034. 1414 Degrees aims to capitalise on this trend by integrating SiNTL technology with its existing silicon-based solutions, including SiBrick®, SiBox®, and SiPHyR™.
Following the licence execution in October 2025, the company plans to produce SiNTL samples for Original Equipment Manufacturers (OEMs) by early 2026, with testing and potential supply agreements targeted for the second half of the year. This accelerated timeline reflects confidence in the technology’s readiness and market demand.
Funding and Strategic Fit
To support this expansion, 1414 Degrees has raised $1.214 million through a placement at $0.042 per share, attracting strong support from existing and new sophisticated investors. The funds will primarily advance the Aurora Battery Energy Storage System project and the development of SiNTL technology.
The acquisition complements 1414 Degrees’ broader strategy of industrial decarbonisation and energy storage innovation. By bridging thermal energy storage and advanced battery materials, the company positions itself at the forefront of clean energy technology integration.
Expert Endorsements and Future Outlook
Dr Kevin Moriarty, Executive Chairman, highlighted the potential for SiNTL to overcome silicon anode limitations and create shareholder value through diversification into the fast-growing battery market. Meanwhile, Professor Michael Wagner, the technology’s inventor, emphasised the breakthrough nature of the aluminium-coated nanoparticles and their compatibility with commercial battery production.
As 1414 Degrees moves towards OEM engagement and potential large-scale manufacturing, the industry will be watching closely to see if this promising technology can translate from lab success to market impact.
Bottom Line?
1414 Degrees’ bold move into silicon anode technology could reshape its growth trajectory amid soaring demand for next-generation batteries.
Questions in the middle?
- How quickly can 1414 Degrees scale SiNTL production to meet OEM demands?
- What competitive advantages will SiNTL hold against other silicon anode technologies?
- How will the placement dilution impact shareholder value in the near term?
