We co-deploy Enhanced Rock Weathering and Biochar, then prove every ton removed with Physics-Informed Neural Networks at 99.8% verification confidence.
Standard MRV platforms use naive AI models that confuse the rapid, short-lived salt release from biochar (the "Ash Spike") with genuine silicate weathering. The result: billions in subprime carbon credits that represent zero actual CO₂ removal.
Three interlocking systems that transform raw soil telemetry into deterministic, audit-grade carbon credits. No guesswork. No approximations. Pure physics.
An in-ground sensor array measures dielectric permittivity, soil temperature, pH, electrical conductivity, and precipitation in real-time. Data streams at 15-minute intervals via encrypted LoRa mesh.
Our PINN doesn't just fit data — it enforces the laws of physics. Richards' Equation governs water flow. Nernst-Planck governs ion transport. The network separates the fast-fading biochar "noise" from the slow, permanent basalt weathering signal.
Every data point, model inference, and credit issuance is anchored via Merkle Trees on-chain. Immutable provenance from sensor to credit, enabling uncompromising Ex-Post crediting with full audit trail.
A natural, accelerated carbon cycle — permanently sequestering CO₂ as stable oceanic bicarbonate for over 1,000 years.
Rainwater absorbs atmospheric CO₂, forming carbonic acid — nature's primary weathering agent.
Crushed basalt and biochar are co-applied to agricultural soils, accelerating natural weathering by orders of magnitude.
Carbonic acid dissolves silicate minerals, releasing calcium and magnesium ions bound to bicarbonate (HCO₃⁻).
Dissolved bicarbonate is carried by groundwater and rivers toward the ocean — a natural, irreversible conveyor.
Bicarbonate integrates into oceanic alkalinity — a thermodynamically stable sink with millennial-scale permanence.
Not a whitepaper. Not a pilot. Active, sensor-instrumented fields generating verified carbon removal today.
Basalt remineralizes depleted soils, restoring optimal pH and unlocking nutrient availability for higher crop productivity.
Enhanced soil biology, improved water retention, and reduced erosion create compound ecological benefits across deployment zones.
Equitable benefit sharing with smallholder farmers — generating additional income streams while building climate resilience at the community level.