BBS:      TELESC.NET.BR
Assunto:  Big Tech eyes orbital data centers
De:       Mike Powell
Data:     Tue, 12 May 2026 09:01:06 -0500
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 * Originally in: SF_Reality

Big Tech eyes orbital data centers for "near continuous" solar power

Date:
Tue, 12 May 2026 11:05:49 +0000

OPINION - Sean McDevitt, Partner at Arthur D. Little

AIs data center boom is constrained by Earths limits, pushing innovation into 
orbit.  Across the globe, the rapid
deployment of AI infrastructure is running up against physical limits. Rather 
than technology, AI data centers currently face constraints caused by access 
to power, water for cooling, and delays in receiving building permit 
approvals that in some cases now stretch for seven years.

Providing a potential alternative, orbital data
centres are moving from being purely theoretical to technically feasible. 
While they wont meet every need, they do offer a way to bypass terrestrial 
bottlenecks, when they are expected to come online in the next 5-7 years. 
Understanding AI data center constraints The future growth of AI relies on 
access to sufficient compute power, delivered through global, large-scale 
data centers. Deploying this infrastructure relies on speed, but three key 
constraints are dramatically slowing down data center construction.
 
Given their enormous energy needs, availability of power is the first 
critical bottleneck. For example, EU data centers are expected to represent 
4% of the regions electricity demand (~108 TWh) by 2030 - more than the 
current annual electricity consumption of the Netherlands. 

Power constraints are dominating data centerbuilding timelines, especially in 
major hubs. In Northern Virginia, USA, new-connection waits can be up to 
seven years. 

Thermal management introduces the second crucial constraint. Water-based 
cooling systems substantially increase local consumption, and water-stress 
exposure affects numerous data center regions, leading to operational and 
reputational risks for developers. 

Finally, regulatory hurdles compound these physical limitations. Community 
resistance to data centers has grown, dramatically extending project 
timelines and increasing stakeholder management costs.

These constraints matter because AI economics reward speed. AI model 
generations turn over every 12-18 months, meaning that infrastructure that 
arrives after the model-refresh cycle delivers diminished returns. Developers 
are therefore looking for new options to overcome these challenges, including 
through orbital data centers. What are orbital data centers? Orbital data 
centers are compute hardware (processors, memory, storage) hosted by 
satellites in Low Earth Orbit (LEO). These operate at altitudes of 400- 1,400 
km above the Earths surface and travel around the Earth every 90- 120 
minutes. 

A recent demonstration successfully tested an H100-class GPU payload in 
space, marking a tangible step toward space-based AI infrastructure.

It is important to understand that the vision for orbital data centers is not 
hyperscale facilities in space. 

Rather, its a modular, networked layer of satellites designed for workloads 
where orbit provides structural advantages, such as near-continuous solar 
exposure for power, a passive thermal environment for cooling, lower 
communication latency than deep space deployments, proximity to 
space-generated data , and/or geopolitical resilience. 

All of this means that for workloads where these factors matter more than 
millisecond latency, LEO satellites offer a way to bypass terrestrial 
bottlenecks. The critical building blocks for orbital data centers Even as 
the hardware advances, the success of orbital data centers requires systems 
engineering rigor across six important building blocks: 

 1. Continuous solar power at scale Certain orbital regimes (e.g., dawn-dusk 
Sun-synchronous orbits) can provide near continuous solar exposure. However, 
high-specific-power, radiation tolerant solar arrays, and resilient energy 
storage are needed to handle transients and contingency eclipse events. 

 2. Effective thermal management Even for satellites illuminated by the Sun, 
a few minutes of shadow occur during each orbit, leading to a temperature 
spread from +120C to -250C. Thermal management  both within the satellite and 
in releasing heat into space  is therefore critical. 

Efficient thermal management, including heat spreading, conservative power 
density, and intelligent workload scheduling, becomes key to performance. 

 3. Resilient, modular compute platforms Radiation hardening, redundancy, and 
autonomous operation are baseline requirements. Because AI economics depend 
on a regular cadence of hardware -refreshes, platforms need upgrade pathways, 
swappable units, and servicing strategies to maintain high utilization rates. 

 4. High-throughput network links Data needs to move efficiently from orbital 
data centers. For non-geostationary modules, optical inter-satellite links 
are needed to exchange data before transmitting it to Earth. Robust, scalable 
ground gateways are also required to receive large data volumes and route 
insights securely. 

 5. Reusable heavy-lift access to bring down launch costs Launch costs 
currently account for about 40% of total required investment. 

Reusable launch systems like SpaceXs Starship, which targets sub-$100/ kg 
versus historical rates of $2,000-$10,000/ kg, are fundamentally reshaping 
orbital data center economics by making deployments at scale commercially 
viable. 

 6. In-orbit assembly and servicing Large orbital data centers require 
robotic assembly of modular units and periodic hardware refresh. This 
mandates standardized docking interfaces and autonomous operations to scale. 
Minimizing these in-orbit services may help reduce time to market but may 
increase the number of satellites needed. How users will adopt orbital 
compute While they seem like science fiction, orbital data centers may sound 
more visionary than they actually are. 

Rather than fully migrating to space, operators will deploy a new data 
channel (much like the one emerging in mobile communications with OneWeb, 
Starlink, and Kuiper) and use orbital capacity only where it removes a 
greater bottleneck than it introduces, especially in three areas: Satellite 
operators and defense users can execute preprocessing and inference in orbit, 
shrinking downlink volumes while accelerating targeting, alerts, and 
situational awareness. Providing sovereign, off-planet storage of critical 
archives and immutable audit logs for extreme continuity protection and 
tamper resistance. For batch-compute workloads that prioritize energy 
availability over millisecond responsiveness. Understanding the challenges 
and opportunity While orbital data centers provide a tangible opportunity for 
AI, constraints remain. For starters, launch costs, platform mass, 
utilization rates, and operational lifetime must exceed the costs of 
terrestrial delays due to power, water, and permitting issues. 

Second, autonomous fault management, debris management, credible servicing 
pathways, and upgrade strategies will determine how often hardware requires 
refreshing and therefore effective cost per compute hour. 

Third, orbital availability, spectrum allocation, and cybersecurity 
frameworks will shape deployment speed, permissible actors, and operational 
boundaries. As mentioned previously, latency is an issue, limiting the types 
of workload that can be deployed in space. Combining terrestrial and orbital 
data centers Increasingly, the data center industrys constraints are not 
about technology. Orbital compute will not eliminate every bottleneck, but 
for specific workload types, it offers a way to avoid power queues, heat 
limits, and permitting timelines by converting physical constraints into 
architectural opportunities.

This article 
was produced as part of TechRadar Pro Perspectives , our channel to feature 
the best and brightest minds in the technology industry today. 
 The views expressed here are those of the author and are not necessarily 
those of TechRadarPro or Future plc. If you are interested in contributing 
find out more here: https://www.techradar.com/pro/perspectives-how-to-submit

Link to news story:
https://www.techradar.com/pro/big-tech-eyes-orbital-data-centers-for-near-cont
inuous-solar-power

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 * Origin: Capitol City Hub (1:2320/105)

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