Modeled Multi-Stage Direct
Energy Conversion

A developmental platform aiming to improve usable electrical extraction from isotopic decay through a staged architecture with zero moving parts.

Scalable Platform Roadmap

PHASE 1: TORRIDEX SMALL

Remote / Autonomous

Status: Modeled targets under laboratory validation.

Remote power pathway designed for long-term autonomous systems and sensors, minimizing reliance on chemical battery lifecycles.

PHASE 2: TORRIDEX POWER

Aerospace & Defense

Status: Architectural roadmap.

Higher-power platform targeting vibration-free, solid-state reliability for critical remote environments and defense applications.

PHASE 3: TORRIDEX WASTE

Industrial Scale

Status: Long-term development pathway.

Long-term industrial pathway for high-radiation thermal environments. Designed to utilize residual heat and radiation fields for scaled energy recovery.

The Technology

TorrideX is designed to improve usable electrical extraction from isotopic decay through a staged plasma-mediated conversion architecture, targeting reduced thermalization losses.

Isotope Source ⟶ Plasma Environment ⟶ Staged Extraction ⟶ High-Efficiency Power

1. The Chamber

Radioisotope-induced non-equilibrium plasma within a modular sealed chamber. Designed to operate continuously without combustion or complex moving parts.

2. Charge Transport

Crossed electric and magnetic fields are used to shape charge transport and reduce recombination losses within the active environment.

3. Staged Harvesting

Energy extraction is modeled across direct electrostatic collection, inductive coupling, and advanced thermoelectrics for an optimized system approach.

Target Specifications Roadmap

System Efficiency	Modeled multi-stage targets under validation
Power Output (Per Module)	Scalable roadmap (Micro to Industrial parameters)
Operational Lifespan	Targeting long-term autonomy (Isotope dependent)
Energy Extraction Modes	Direct DC, Inductive AC, Thermoelectric/Thermal
Scalability	Modular architecture design
Mechanical Profile	Targeting zero moving parts (Solid State models)

Safety & Regulatory Pathway

Containment

The architecture is designed with layered encapsulation barriers to prioritize structural integrity in extreme operational environments.

Shielding

Engineered to internalize emissions, utilizing high-energy particles within the working gas volume before they reach the outer boundary.

Compliance Target

Development aligns with foundational regulatory frameworks, planning for full traceability and structured end-of-life cycle management.

Modeled Multi-Stage DirectEnergy Conversion