Challenge:
"We want to decarbonize — but not at the cost of reliability."
Solution:
We redesign energy matrices using physics-based models that balance emissions, cost, and resilience.
Led the transition from thermal generation to a mixed grid-connected and solar-powered system, ensuring compliance with environmental regulations while maintaining grid stability. The transition achieved carbon reduction targets without compromising operational integrity.
DECA® Decarbonized Ecosystem Assessment Tool
Full energy-mass-economic flow modeling, including natural remediation capacity
Linked to Fidelis RAM models to assess impact of intermittent supply on asset availability
Achieved carbon reduction targets without compromising operational integrity
Physics-Based Energy Modeling
We model actual thermodynamic constraints, grid stability requirements, and intermittency effects — not just spreadsheet projections of renewable capacity.
Reliability-Constrained Decarbonization
Through DECA® and Fidelis integration, we ensure that renewable transitions don't create new reliability risks — backup capacity, storage, and grid resilience are designed in from day one.
Ecosystem-Level Assessment
DECA® models the full energy-mass-economic system, including natural carbon sequestration capacity, waste heat utilization, and circular economy opportunities — not just generation swaps.