When a company reports results that suggest it can do what others have not widely demonstrated, markets pay attention. HPQ Silicon Inc.’s $HPQ / $HPQFF GEN4 21700 cells just crossed 7,030 mAh at 0.55V lower cutoff – a level that, to the company’s knowledge, has not been widely reported in publicly available data for an industrial-format cell under comparable conditions.
This reflects more than just capacity, including the ability to cycle under extended voltage conditions in testing that would typically result in significant degradation in conventional lithium-ion batteries, with less than 2% degradation over 70 cycles. HPQ Silicon, backed by up to $3 million in Canadian federal funding and exclusive North American rights to Novacium’s silicon-anode technology, is now advancing toward commercialization, with the CEO stating the company is in discussions with drone manufacturers, military groups, and e-mobility partners.
WHAT YOU NEED TO KNOW
Voltage Breakthrough:
0.55V cutoff may provide approximately 5% more usable energy based on internal estimates, typically inaccessible in lithium-ion cells operated at conventional cutoffs.
Cycle Stability:
Less than 2% degradation over 70 cycles at extended voltage — described by the company as a performance level not commonly observed under similar conditions.
Production Pathway:
HPQ is advancing a production plan with capacity in the range of approximately 600,000 21700 cells annually, with discussions underway with drone, military radio, and e-bike manufacturers.
Government Backing:
Up to $3M federal grant from Natural Resources Canada supports HPQ’s first battery production facility in Canada and is intended to help strengthen domestic supply chains.
Federal Support:
Canada’s Minister of Energy and Natural Resources has previously stated: “Projects like HPQ Silicon’s strengthen Canada’s ability to manufacture components for high-performance batteries and are creating a world-class battery ecosystem.”
STRATEGIC IMPLICATIONS
The battery industry faces significant performance constraints. Conventional graphite anodes in 21700 cells are commonly reported in the ~5,000 mAh range. Silicon-enhanced cells from leading developers are reported in the ~6,000–6,500 mAh range. But there’s a second problem that receives less attention: every lithium-ion battery carries energy below the commonly used ~2.5V cutoff. Go below that threshold with graphite, and you risk transforming a rechargeable battery into a single-use cell because the material can degrade rapidly. The industry has largely lived with this constraint for years.
HPQ’s GEN4 silicon-anode material is designed to operate in this lower-voltage region. By cycling down to 0.55V with under 2% degradation over 70 full charge-discharge cycles in testing, the company reports that it has accessed energy that is typically not utilized. The company states that internal calculations indicate this could translate to about 5% more runtime from the same physical battery under comparable conditions. For a military drone operating at the edge of its range, this could be meaningful for performance and runtime. For an electric bike commuter, it could mean additional range without adding weight. For defense contractors, it represents a potential alternative high-performance option in a segment where performance differentiation is important.
The timing is notable. Canada has announced large-scale spending programs targeting domestic industrial capacity and clean-energy infrastructure. The U.S. is reshoring critical supply chains. Europe is seeking additional non-Asian battery materials. HPQ holds exclusive North American rights to commercialize its GEN3 and GEN4 silicon-based anode materials with Novacium. The company is focusing on applications where performance, supply-chain security, and operational advantage can support premium positioning: drones, military radios, handheld power tools, and stationary energy storage.
CEO Bernard Tourillon:
“What we’ve demonstrated isn’t just higher capacity — it’s a new operating mode for our cells under test conditions. We can access energy that conventional batteries typically leave on the table, and we’re doing it with cycle stability that holds up over dozens of charge-discharge cycles. The phone’s ringing. We’re in discussions with drone manufacturers, defense departments, and niche mobility players who are evaluating exactly what we’ve built. We’ve gone from ‘Can it work?’ to ‘How fast can you scale?'”
INVESTOR TAKEAWAY
HPQ Silicon has reported a significant test milestone. The 7,030 mAh result at extended voltage is not presented as a one-off curiosity — it is described by the company as a performance level not widely reported in publicly available data for industrial 21700 cells under comparable conditions.
These results are based on internal testing and have not been independently verified, and may not be representative of commercial performance. Federal funding helps support the path toward scaled production. Early interest and testing discussions in high-value verticals indicate potential commercial pathways.
The company’s exclusive North American license with Novacium and domestic production strategy align with government priorities around supply-chain security and critical materials independence. With an initial production pathway defined and a stated roadmap toward commercialization, HPQ is positioning its battery initiative as a developing commercialization story entering its next phase.