AEGiSS ESCW delivers 1,000 MW from a 20-acre site — zero fuel, zero CO₂, integrated cooling and potable water. The lowest VALCOE of any generation technology at $64 / MWh, operational within 18 months.
VALCOE calculated by Eshcol Energy Corp using Lazard LCOE v18.0 methodology — company-internal calculations, not independently verified by Lazard & Co.
AI compute demand is growing faster than the grid can support. Data centers need power that is dense, clean, fast to deploy, and independent of grid connection queues.
In the UK and US, transmission connection queues now stretch years. Hyperscalers cannot wait — they need power at the fence line, not at the substation.
5yr4,000 MW of solar requires 30,000 acres. 2,700 MW of wind requires 86,400 acres. Neither dispatches on demand. Neither eliminates cooling cost. AEGiSS delivers 1,000 MW from just 20 acres — over 1,500× more land-efficient than wind.
1500×Legacy data centers spend 40% of their energy bill on HVAC. AEGiSS ESCW replaces the entire cooling system while generating electricity — eliminating the largest operational cost.
40%A distributed polygeneration platform that captures ambient thermal energy, converts it to electricity, eliminates cooling loads, and produces potable water — from a single modular unit.
120 towers per 10 MW field — ambient heat capture
33 MWh integrated buffer — continuous dispatch
16 power modules · 212°F transport fluid · 3× output (2026)
95% waste heat recaptured · replaces HVAC · no heat rejection
~100% power to process · 4,600 gpd potable · zero emissions
No combustion, no fuel supply chain, no carbon or fuel price risk. The energy source is ambient thermal energy — effectively inexhaustible and unpriced at the point of capture.
For data centers, the ESCW configuration replaces the entire HVAC system. Waste process heat from the data hall is recaptured and fed back into the generation cycle, eliminating 40% of operating cost.
Each 10 MW building block occupies ⅓ acre. Stack modules to reach any scale — from 20 MW to 1,000 MW — on 20 acres. The same engineering, the same supply chain, linear cost scaling.
March 2026 testing confirmed transport fluid can reach 212°F with no degradation of cell lifetime stability. Power output increases at least 3× over previous models, opening the utility-scale market for existing plant boosting.
Each 20 MW plant produces 4,600 gallons per day of potable water as a byproduct — eliminating social resistance and enabling deployment in water-stressed regions where conventional power faces opposition.
AEGiSS is ranked #1 across the five dimensions that matter most to energy investors and offtakers.
Lowest value-adjusted levelised cost of any generation technology. Includes energy, storage, cooling, and water in a single figure. Calculated on Lazard 2025 methodology by Eshcol Energy Corp — company-internal figures, not independently verified by Lazard.
Remote monitoring, unmanned operation, and zero consumable inputs mean operating costs stay flat over the plant's 75-year life. No fuel volatility. No carbon price exposure.
Unlike solar (25%) or wind (35%), AEGiSS dispatches 24/7, 365 days a year. Integrated thermal storage ensures continuous output regardless of ambient conditions.
~40× greater power density than nuclear, 375× more land-efficient than solar, and 1,600× more efficient than wind. Enables brownfield, rooftop, and urban co-location projects impossible with any other clean generation technology.
3–6× faster than gas with CCS. 5–8× faster than nuclear. The fastest path from investment decision to revenue-generating asset of any clean baseload technology.
Designed for a 75-year operating life with no major overhaul requirements. A single 100 MW plant generates $1.93–2.05B NPV over its lifetime at current grid prices.
| Technology | AEGiSS ESCW | Gas + CCS | Nuclear | Solar PV | Onshore Wind |
|---|---|---|---|---|---|
| VALCOE / MWh | $64 | $130–190 | $131–210 | $40–60* | $26–50* |
| Land / GW | 20 acres | ~500 acres | 823 acres | 7,500 acres | 32,000 acres |
| Capacity factor | 100% | 80–90% | 90–92% | 20–28% | 30–40% |
| Time to operation | 15–18 months | 4–7 years | 10–15 years | 2–3 years | 2–4 years |
| Carbon emissions | Zero | Residual CO₂ | Near-zero | Lifecycle only | Lifecycle only |
| Cash up-front · 100 MW | $188M | $120–155M† | $6–9B | $100–130M | $130–160M |
| Integrated cooling | Yes — ESCW | No | No | No | No |
* Solar and wind LCOE does not include storage, capacity firming, or cooling. VALCOE comparison basis: Lazard 2025 methodology, 7.7% real WACC, 100 MW scale.
† Gas CCGT cash up-front shown as single-plant figure ($120–155M). A fair lifecycle comparison requires 3 CCGT plants over 75 years (to match AEGiSS's 75-year design life vs. CCGT's ~30-year life), giving a true capital equivalent of ~$360–465M before fuel, carbon, and O&M costs.
AEGiSS is delivered by a consortium of proven specialists. Each partner brings domain expertise critical to commercial deployment — from manufacturing to data-center EPC to independent engineering validation.
Systems integration lead with background spanning Siemens Energy and Groq. Brings deep experience in energy infrastructure deployment and AI-era power systems. Incorporated in Delaware, USA.
Specialist thermal recapture engineering company providing the core generation technology. Responsible for power cell design, thermal concentrator tower specifications, and ongoing R&D including the March 2026 transport fluid breakthrough.
20-year engineering, procurement, and construction leader specialising in data center infrastructure. Responsible for the ESCW cooling integration, site build, and commissioning.
105-year consulting firm of engineers, technical specialists, and project managers. Provides independent technical validation, VALCOE methodology review, and project assurance — giving investors third-party confidence in all performance claims.
79-year history as a Department of Defense-approved contract manufacturer. Responsible for prototype build and series production of power cell components. Quality management systems provide manufacturing process confidence.
Independent testing laboratory to conduct Alpha validation testing on the completed prototype. Selection in progress. Results will be published to all investors following the $1M seed funding milestone.
We are raising $1M to complete prototype construction, conduct independent alpha validation, and bring AEGiSS to commercial deployment by Q3 2026.
Final engineering drawings, component specifications, and bill of materials delivered by USA GTE and Syncro. Design review with HH Angus completed.
Full power cell assembled by Syncro at their DoD-approved manufacturing facility. Incorporates 212°F transport fluid specification from March 2026 update.
Independent testing by selected third-party lab. Pass/fail criteria defined in advance. Results published to all investors. Validates power output, thermal cycle stability, and VALCOE assumptions.
Series A fundraise opens. First customer deposits for 20 MW plants. Target: 3 signed LOIs with data center operators, co-location providers, or utility customers.
Technical validation at prototype scale is the primary risk acknowledged by the Eshcol team. The $150k independent alpha testing milestone is specifically designed to de-risk this before Series A. All investors will receive the full validation report.
Whether you're evaluating the $1M seed round or planning ahead for our Series A, we'd like to hear from you.
Full AEGiSS ESCW investor presentation including CAPEX model, VALCOE analysis, and financial projections
Custom cost-benefit analysis for your specific use case (data center, utility, brownfield)
Technical deep-dive call with the Eshcol team and USA GTE thermal engineers
HH Angus independent validation summary and VALCOE methodology report