The universe is full of information that classical sensors cannot read. We build quantum devices that harvest their own energy from the environment, and record what they sense — permanently — without batteries, without wiring, without maintenance.
We are building a new class of sensing device — one that harvests its own energy from environmental motion, measures what it finds, and writes that measurement into permanent memory that survives for hours without any refresh. No battery. No cable. No scheduled maintenance. Just a device that works, indefinitely, wherever you place it.
That single constraint — the battery — determines where sensing can happen, how often it fails, and what it costs to maintain. In cold-chain logistics, pharmaceutical cold chain alone loses $35 billion per year to spoilage from monitoring gaps that exist precisely because maintaining battery-powered sensors at scale is economically untenable.
The constraint has a physics-level solution. We are building it.
The invisible substitute: today's standard is TTI labels — chemical indicators that change color to show temperature excursions. They are passive, permanent, and require no power. They also produce no data, cannot be remotely read, and cannot distinguish a brief spike from a prolonged excursion. Our device replaces the TTI with a precise digital record.
We did not improve the classical sensor. We replaced it with something modeled on biology — five functional layers that operate as a single self-sustaining organism. Each layer has a specific role. The system is only possible because all five work together in a closed loop.
The self-powered sensing architecture solves a constraint — the battery — that currently limits where precise measurement can go. Cold-chain pharmaceutical monitoring is our immediate focus. The same platform, without modification, applies to every domain where continuous sensing has been impossible because of power and maintenance requirements.
We have completed a rigorous computational validation program — Several digital-twin simulations of the full sensor circuit through Classical Quantum Emulation, all gates passed. Physical prototype construction is underway. Our work supports U.S. national priorities in quantum sensing.
We're building the instruments to listen. If you work in pharmaceutical logistics, cold-chain infrastructure, environmental monitoring, or life sciences — and you need sensing where batteries cannot go — we want to hear from you.