Because the future is inevitable.
MODULAR ADAPTABLE PATENTED DESIGN
Foundation, blueprint, racks, geodesic shell, cupola — the dome assembles like a layer cake. Pick a power density to see the cooling change.
Power density
Same chambers, denser racks, copper-trim CDU manifold overhead.
Speed & savings
Two questions every operator asks. Two answers built into the geometry.
Speed to market
Modular fabrication, geodesic shell, and behind-the-meter power compress the build envelope from years to months — and turn delivery risk from a wildcard into a schedule.
12–24 months of earlier revenue.
Watertight build ~12 weeks. First-revenue dome typically live <12 months from groundbreak.
Savings
Per 50 MW campus. Lower PUE, near-zero water, and earlier go-live all compound into a different financial profile from day one.
Saved per 50 MW campus over 5 years.
Representative model. Assumptions: 50 MW IT load, $0.08/kWh wholesale energy, PUE 1.13 vs 1.50 baseline, municipal water rate, $0.10/kWh contracted revenue, 18-month earlier go-live. Real numbers depend on site, contract structure, and energy mix.
Biomimetic Engine
The geodesic dome isn't a logo – it's the engine that aerodynamically moves heat the same way the planet does.
01 · Passive convection
The dome's curved interior creates natural convection currents that move heat without the chiller plants and water loops conventional designs depend on.
02 · Built for AI density
Hybrid air + direct liquid + immersion cooling supported out of the box. Vendor-neutral hardware. Scalable from a single 10–20 MW dome to multi-dome campuses at 50, 100 MW+.
03 · Geometry that compounds
Geodesic triangulation distributes structural load with roughly 30% less material than a comparable rectangular shell, opens a column-free interior for any rack layout, and assembles in modular phases.
The proof
Source: ServerDomes engineering benchmarks vs. industry typical hyperscale shell.
Next-Gen Power
Power is now mission critical. Interconnection queues stretch four to seven years in the markets where AI demand is heaviest. We pair the dome with on-site, behind-the-meter generation — natural gas today, with optionality for solar, storage, hydrogen, and waste-heat as economics evolve.
Behind-the-meter · primary
On-site natural-gas generation sized to the campus. Sub-$0.10/kWh delivered. Independent of utility queue timing. Dispatchable, islanded, black-start capable.
Grid-parallel · optional
Where utility capacity is available and economics support it, we interconnect for redundancy and surplus sales — without depending on the queue to energize.
Hybrid · future-fuel ready
Architecture accepts solar PV, battery storage, hydrogen blends, RNG, and waste-heat reuse as they mature. Fuel-source optionality is part of the design, not an afterthought.
BTM
Gas baseload
30+ GW
Transmission crossing target sites by 2028
<$0.10
per kWh delivered
The economics
Geodesic structure uses fewer pounds of material per square foot of usable compute floor. Modular fabrication compresses construction risk and timeline.
When the building does the cooling, the chiller plant shrinks or disappears. That cost comes out of every monthly bill for the life of the asset.
Hybrid air + liquid + immersion support means we're not retrofitting in two years. The same dome carries today's racks and tomorrow's GPUs.
We deploy in dome-scale increments (10–20 MW each), so capacity matches contracted demand. No stranded shells. No oversized substations waiting on tenants.
Regions
ServerDomes is engineered to deploy where AI demand and clean-power capacity are emerging fastest.
PLANETARY IMPACT
Roughly 90% less water. Up to 27% less power per unit of compute. Materially lower embodied carbon per MW than conventional shell construction. Real numbers, sourced and shareable.
Domes are quieter, lower-profile, and less visually disruptive than rectangular hyperscale boxes. Behind-the-meter power means fewer new transmission lines crossing the landscape. Local jobs during build and operation.
High-density training and inference workloads supported from day one — without the water, land, or grid impacts that have stalled conventional builds in dozens of communities.
Watertight structure in roughly 12 weeks. Live in under 12 months. Every month earlier is a month of compute delivered, revenue earned, and AI workloads unblocked.
EMERGING REGIONS
USA, India, Europe, and Canada. Drag the globe to explore.
4 EMERGING REGIONS