Quantum Data Center
Containerized Data Center Optimized for Quantum Computer Operations
⚠️ Vibration, EMI, Magnetic Field Shielding & Cryogenic Cooling
Quantum computers require a completely different operating environment than conventional computers. Qubits operate stably only at temperatures near absolute zero—approximately 15 millikelvin (mK). Even the slightest vibration, electromagnetic interference, or Earth's magnetic field can cause quantum state collapse.
DOBE Computing's Quantum Data Center is a purpose-built containerized data center designed to meet these extreme requirements.
Quantum Data Center - DOBE Computing
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QUANTUM Data Center Key Features
Purpose-built infrastructure designed to meet the extreme requirements of quantum computing
01
Cryogenic Cooling System
Dilution Refrigerator compatible
Near absolute zero (-273°C) environment
02
Vibration Isolation
Anti-vibration floor & seismic system
Prevents qubit decoherence
03
EMI Shielding
Faraday Cage design
Complete electromagnetic interference blocking
04
Redundant Power System
UPS + Generator redundancy
Zero downtime for uninterrupted computing
05
Precision Environmental Control
Temperature, humidity, pressure control
Cleanroom-grade environment management
06
Modular Scalability
Phased infrastructure expansion
as research scale grows
🔬 Quantum Computer vs Traditional Server
| Category | Traditional Server | Quantum Computer |
|---|---|---|
| Operating Temperature | Room temp (20~25°C) | Cryogenic (~15mK) |
| Cooling Method | Air / Liquid cooling | Dilution Refrigerator |
| Vibration Sensitivity | Low | Extremely High |
| EMI Sensitivity | Moderate | Extremely High |
| Power Stability | Important | Critical (Zero Downtime) |
| Environmental Control | Standard | Precision Required |
🎯 Applications
🔬
National Research Labs
Quantum computing R&D
Quantum cryptography
Quantum cryptography
🏛️
University Research
Quantum mechanics experiments
Qubit research
Qubit research
🏢
Corporate R&D
Drug discovery simulation
Financial optimization
Financial optimization
🛡️
Defense & Security
Quantum cryptography
Post-quantum encryption
Post-quantum encryption
⚛️
Energy & Materials
Molecular simulation
New materials R&D
New materials R&D
📐 Quantum Data Center Specifications
📦
20ft Container
6,058 × 2,438 × 2,896mm
- Dilution Refrigerator 1~2 units
- Space Configuration Control room separable
- EMI Shielding Grade MIL-STD-461G
- Power Capacity 50~100kVA
- Cooling Support Cryo + Standard
🚛
40ft Container
12,192 × 2,438 × 2,896mm
- Dilution Refrigerator 2~4 units
- Space Configuration Control + Equipment rooms
- EMI Shielding Grade MIL-STD-461G
- Power Capacity 100~200kVA
- Cooling Support Cryo + Standard
❓ Quantum Data Center FAQ
Q1
What makes a Quantum Data Center different from a traditional data center?
Quantum computers operate at cryogenic temperatures near absolute zero (~15mK) and are extremely sensitive to micro-vibrations and electromagnetic waves. This requires specialized designs including Dilution Refrigerator accommodation, anti-vibration structures, and EMI shielding. The operating environment is completely different from conventional servers.
Q2
What are the advantages of containerized quantum computing infrastructure?
Rapid deployment without new building construction, and relocatable when needed. As research scales up, you can expand modularly, reducing initial investment burden. Installation is possible in outdoor areas or parking lots near existing research buildings, maximizing space utilization.
Q3
What is a Dilution Refrigerator?
A dilution refrigerator uses a mixture of Helium-3 and Helium-4 to achieve cooling down to approximately 10~20 millikelvin (mK), near absolute zero (-273.15°C). This ultra-cold environment is essential for superconducting qubits to maintain their quantum state. Leading manufacturers include Bluefors (Finland) and Oxford Instruments (UK).
Q4
What quantum computing technologies do you support?
We support superconducting qubit systems from IBM and Google, IonQ's ion trap technology, photonic quantum computers, and more. Each technology has different cooling temperature and shielding requirements, so we provide optimized infrastructure tailored to your specific quantum computer specifications.
🚀 Consult with our experts on Quantum Computing Infrastructure