Advancing Electrolytic Plasma Cavitation for Sustainable Energy Generation
Diadon Acs 02-13-2025
1. Executive Summary
Project Proteus is a novel approach to energy generation through Harmonic Hydrogen Fusion (HHF)—a method that condenses hydrogen plasma at the boundary of a hydrogen-metal lattice using Electrolytic Plasma Cavitation. This technology explores the interaction between plasma oscillations, lattice structures, and nuclear-level effects to progress efficiency in sustainable and decentralized energy generation.
Our research aims to develop a functional HHF reactor that can provide clean, abundant energy with applications in:
- Distributed power generation
- Sustainable heating solutions
- Water desalination
- Nuclear waste remediation
To advance this breakthrough, we seek funding across four strategic phases to establish an experimental foundation, validate results, optimize technology, and transition into manufacturing.
2. Background & Motivation
The global energy sector faces increasing challenges related to sustainability, efficiency, and environmental impact. Conventional energy sources contribute to pollution, geopolitical instability, and economic inefficiencies.
Project Proteus is investigating a potential alternative: a Harmonic Hydrogen Fusion reactor utilizing light water and a specialized metal lattice to induce low-energy nuclear reactions (LENR). If successful, this approach could redefine energy generation, offering a scalable and environmentally responsible alternative.
Potential applications include:
- Decentralized Power Solutions – Providing off-grid energy independence.
- Industrial and Residential Heating – Reducing reliance on fossil fuels.
- Water Purification & Desalination – Addressing global freshwater shortages.
- Nuclear Waste Remediation – Exploring LENR applications in reducing radioactive materials.
3. Progress So Far
Despite operating on a self-funded budget, interesting observable phenomena have been achieved:
- Development of plasma cavitation reactors generating controlled energy bursts.
- Identification of high EMI (electromagnetic interference) environments, requiring improved shielding and instrumentation.
- Advances in low-profile, transportable circuit designs optimized for plasma oscillation and micro-cavitation control.
One of the primary challenges is accurate measurement of energy output and potential nuclear effects. EMI interference has made precise temperature and radiation measurements difficult. Additional funding will allow for specialized EMI-resistant sensors and diagnostic tools to validate experimental results.
4. Next Steps & Research Plan
The next phase of research will focus on closed-loop water circulation, enhanced diagnostics, and nuclear signature detection. Key objectives include:
- Steam Distillation & Recirculation
- Implementing a heat exchanger and borosilicate glassware to efficiently recycle water into the reactor, to breed further condensed hydrogen.
- Advanced Temperature Sensing
- Using analog computer vision thermometry or EMI-resistant RTDs for precise heat measurement.
- High-Accuracy Liquid Flow Monitoring
- Installing EMI-resistant flow sensors to track energy transfer efficiency.
- Nuclear Signature Detection
- Deploying CR-39 detectors, X-ray film, and bubble neutron detectors to validate potential LENR activity.
5. Four-Phase Funding Plan & Cost Analysis
| Expense | Purpose | Estimated Cost |
| Oscilloscope (5 GHz) | Plasma oscillation and circuit diagnostics | $1,500 – $3,000 |
| EMI-Resistant RTDs & Flow Sensors | Precision temperature and flow measurement | $500 – $1,500 |
| Borosilicate Glassware | Steam distillation and closed-loop recirculation | $500 – $1,500 |
| Power Supply (0-2 Amp, 0-1000V DC) | Reactor power control and tuning | $1,500 – $3,500 |
| DRSSTC Feedback Circuit | Plasma oscillation control | $1,000 – $3,000 |
| Cathode Materials (Nickel, NiCu, NiTi, etc.) | Hydrogen lattice formation | $500 – $2,000 |
| Platinum Screen (Anode) | High-purity electrolysis performance | $1,000 – $3,000 |
| CR-39 Neutron & X-ray Film | Radiation detection & LENR validation | $2,000 – $5,000 |
| Legal Fees & NPO Formation | Filing for 501(c)(3) status | $1,500 – $3,500 |
| Total Estimated Cost (Phase 1) | $35,000 – $120,000 |
Phase 2: Prototype Refinement & Expansion (Year 2-3) – $150,000 to $300,000
Phase 2 focuses on refining the reactor design, improving measurement accuracy, and expanding experimental capacity.
| Expense | Purpose | Estimated Cost |
| Facility Rental & Utilities (12 months) | Lab space for prototyping and testing | $15,000 – $30,000 |
| Advanced Testing & Validation | CR-39, X-ray, and neutron detection | $10,000 – $20,000 |
| Second-Generation Reactor Prototypes | Enhanced materials and engineering | $25,000 – $50,000 |
| Computational Modeling | Simulations and theoretical validations | $10,000 – $20,000 |
| High-Precision Data Acquisition | Digital EMI-shielded systems | $15,000 – $30,000 |
| Personnel (3-5 Engineers/Researchers) | Expanding research team | $75,000 – $150,000 |
| Expanded Lab Space & Utilities | Accommodating additional equipment | $15,000 – $30,000 |
| Total Estimated Cost (Phase 2) | $165,000 – $330,000 |
Phase 3: Large-Scale Testing & Industrial Feasibility (Year 3-4) – $300,000 to $750,000
This phase is dedicated to long-duration testing, regulatory compliance, and market feasibility assessments.
| Expense | Purpose | Estimated Cost |
| Extended Reactor Testing (Long-Duration Runs) | Stability and reliability evaluation | $75,000 – $150,000 |
| Industrial-Grade Sensors & Measurement Systems | Precision validation of energy output | $50,000 – $100,000 |
| Regulatory Compliance & Safety Testing | Meeting energy sector standards | $30,000 – $75,000 |
| Personnel (5-8 Engineers & Researchers) | Further expanding research capacity | $125,000 – $250,000 |
| Facility Expansion & Upgraded Lab Equipment | Scaling testing capabilities | $20,000 – $50,000 |
| Total Estimated Cost (Phase 3) | $300,000 – $750,000 |
Phase 4: Manufacturing & Market Deployment (Year 4-5) – $750,000 to $1.5 Million+
The final phase transitions Harmonic Hydrogen Fusion from research into practical application through pilot manufacturing and product deployment.
| Expense | Purpose | Estimated Cost |
| Manufacturing Facility Lease & Setup | Small-scale production plant | $100,000 – $250,000 |
| Component Sourcing (Nickel, Platinum, Electronics, etc.) | Bulk materials acquisition | $250,000 – $500,000 |
| Pilot Production (100+ Units) | First commercial-scale test batch | $250,000 – $500,000 |
| Regulatory & Patent Filing | Securing technology IP & compliance | $50,000 – $100,000 |
| Marketing & Distribution Strategy | Commercial launch & investor outreach | $100,000 – $200,000 |
| Total Estimated Cost (Phase 4) | $750,000 – $1.5 million+ |
6. Final Funding Breakdown & Timeline
| Phase | Timeframe | Funding Goal | Key Milestones |
| Phase 1 (Seed Grant) | Year 1-2 | $50,000 – $150,000 | Experimental validation & early data collection |
| Phase 2 | Year 2-3 | $150,000 – $300,000 | Prototype optimization & expanded testing |
| Phase 3 | Year 3-4 | $300,000 – $750,000 | Industrial feasibility & long-term testing |
| Phase 4 | Year 4-5 | $750,000 – $1.5M+ | Manufacturing & commercial deployment |
| Total 5-Year Plan | 2025-2030 | $1.25M – $2.7M+ | Full-scale commercialization of HHF technology |
7. Call to Action: How to Contribute
To bring this transformative energy technology to reality, we are seeking funding from:
- Private investors interested in next-generation energy solutions.
- Government research grants for sustainable energy innovation.
- Philanthropic and open-source science supporters to accelerate LENR research.
Investors and funding partners will gain early access to research breakthroughs, priority in first versions, and recognition in advancing next-generation energy solutions which present value beyond monetary returns.
For funding inquiries, partnership discussions, or further details, please contact: Diadon Acs
diadon@conscious.energy
https://conscious.energy
