The Carbon Mineralization Reactor

Engineering High-Efficiency Ex-Situ Carbonation Systems for Global Decarbonization

Turn atmospheric liabilities into solid assets through the power of precision engineering.

Strategic Objectives

• Master the thermodynamics of accelerated mineral carbonation.

• Design high-pressure vessels optimized for solid-liquid-gas interactions.

• Integrate advanced heat recovery systems to slash operational costs.

• Scale laboratory breakthroughs into industrial-grade surface facilities.

The Core Challenge

While carbon capture is evolving, the challenge remains: how do we store CO2 safely, permanently, and at an industrial scale without relying solely on underground reservoirs?

The Science of Mineral Carbonation

Ex-Situ vs In-Situ Systems

Thermodynamics of Carbonation

Feedstock Selection

Kinetics and Reaction Rates

Reactor Geometry and Design

Pressure Vessel Engineering

Heat Exchanger Integration

Mass Transfer Enhancements

Abrasive Slurry Handling

Materials Science and Corrosion

Comminution and Pre-treatment

Supercritical CO2 Utilization

Separation and Carbonate Recovery

Process Control and Automation

Scaling Up from Bench to Pilot

Carbon Accounting and Verification

Industrial Waste Symbiosis

Safety and Risk Management

Economic Modeling of Ex-Situ Plants

The Future of Mineral Engineering

Explore Research Ecosystem

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