Project Development Strategy
PetroDexia has conducted preliminary prospect planning studies for stimulated geologic hydrogen in selected locations in North America, Europe, and India, focused on available geology, public technical data, well information, regional subsurface indicators, existing infrastructure, and industrial scalability potential. These studies include mafic, ultramafic, and sedimentary Fe-rich systems and support our development strategy: identify promising Fe-oxide settings, prioritize areas for validation, and define practical pathways toward pilot planning.
Opportunity Screening
Identify locations for stimulated geologic hydrogen with favorable Fe-oxide systems and tectonic reworking, with consideration of infrastructure and industrial end-use potential.
Technical De-Risking
Evaluate subsurface uncertainty, Fe-oxide mineral systems, fluid pathways, well data, validation needs, economics, and project assumptions, with key inputs feeding into the RDS Framework to reduce geological, operational, and development risk.
Development Strategy
Define practical steps from prospect planning to validation, pilot design, recovery strategy, and scalable industrial deployment, with RDS-informed decisions guiding technical priorities, economics, and field-scale execution.
RDS FRAMEWORK
PetroDexiaβs proprietary Rate-Determining Step (RDS) Framework starts as a data-calibrated model integrating laboratory results, geology, geophysics, petrophysics, field monitoring, and well-performance data. As new data are collected, RDSβ’ is dynamically calibrated and adjusted to improve system understanding, optimize operating strategy, enhance production, and align development decisions with project economics. With scaled field data, RDS is designed to evolve into an AI-assisted optimization platform supporting production-mode selection, including optional dual-mode development where field conditions support it.
Field Development Pathway
PetroDexia designs development pathways that translate subsurface intelligence into practical stimulated geologic hydrogen deployment. Rather than a single-well concept, our approach progresses from prospect planning and validation to pilot design, recovery strategy, field-scale development, and scalable industrial deployment.
Pilot and field designs are adjusted to site geology, Fe-oxide system behavior, infrastructure access, operational constraints, RDS-informed monitoring, and industrial energy needs.
