🚀 What Makes Hanyuan No. 1 Different: The Technology Explained

To understand why Hanyuan No. 1 matters, we must first grasp why most quantum computers are extraordinarily difficult and expensive to operate — and how neutral-atom technology offers a fundamentally different path.

The Superconducting Quantum Computer Challenge

Google’s Willow chip, IBM’s quantum processors, and most leading quantum computers use superconducting qubits — tiny electrical circuits that only exhibit quantum behaviour at temperatures approaching absolute zero:

• Operating temperature: 15 millikelvin (-273.135°C)
• Cooling requirement: Dilution refrigerators costing millions of dollars
• Energy consumption: Massive power draw for cryogenic systems
• Physical footprint: Entire rooms dedicated to cooling infrastructure
• Maintenance: Constant monitoring and expensive helium-3 refrigerants

Neutral-Atom Quantum Computing: A Different Paradigm

Hanyuan No. 1 employs a radically different approach called neutral-atom quantum computing (internationally) or atomic quantum computing (Chinese terminology). Here’s how it works:

Visual comparison showing superconducting qubits vs neutral atom qubits. Neutral atoms are trapped and manipulated using optical tweezers (focused laser beams) at room temperature, whilst superconducting circuits require extreme cryogenic cooling. Source: Quantum computing architecture comparison

The neutral-atom advantage:

• Room temperature operation: Atoms are cooled to ultracold temperatures (near absolute zero) but the quantum computer’s environment operates at room temperature — no cryogenic infrastructure required
• Optical tweezer control: Individual atoms (typically rubidium or caesium) are trapped using focused laser beams called “optical tweezers”
• High-fidelity operations: Atoms are identical by nature, providing inherently consistent qubits
• Scalability: Adding more qubits is theoretically simpler — just trap more atoms in your optical lattice
• Compact footprint: Hanyuan No. 1 fits in three standard equipment racks vs entire rooms for superconducting systems

🏭 The Hubei Advantage: Building a Domestic Quantum Supply Chain

One of the most strategically significant aspects of Hanyuan No. 1 isn’t just the technology — it’s how and where it was built. The project exemplifies China’s broader strategy of achieving technological self-sufficiency whilst leveraging regional industrial strengths.

Optics Valley: China’s Photonics Manufacturing Hub

Hanyuan No. 1 was developed in Wuhan, Hubei Province, home to “Optics Valley” (光谷) — China’s premier optoelectronics and photonics manufacturing cluster. This wasn’t coincidental; neutral-atom quantum computing relies heavily on laser technology and optical components.

“The project leveraged Hubei’s strong optoelectronics manufacturing base to build a domestic supply chain for quantum computing components. Engineers succeeded in producing high-performance lasers that meet the precision control requirements for atomic qubits whilst consuming only one-tenth the energy of comparable foreign systems.”

— Hubei Daily, November 2025

The domestic supply chain strategy includes:

• Laser manufacturing: High-precision lasers for optical tweezer qubit control
• Optical components: Mirrors, beam splitters, optical isolators, and waveguides
• Chip growth and packaging: Complete R&D pipeline from design to system testing
• System integration: Testing facilities and quality control infrastructure
• Cloud platform development: User-friendly quantum computing interfaces

Multi-Institution Collaboration

According to reports, the Hanyuan project involved extensive collaboration across China’s quantum research ecosystem:

• Chinese Academy of Sciences: Innovation Academy for Precision Measurement Science and Technology (lead developer)
• Wuhan University: Quantum algorithm and cloud platform development
• Huazhong University of Science and Technology: Hardware engineering
• Zhongke Kuyuan Technology: Commercial system integration
• Optics Valley Information Optoelectronics Innovation Centre: Component manufacturing
• Wuhan Institute of Quantum Technology: Application development

This model — combining academic research, regional manufacturing strengths, and commercial partners — mirrors successful technology cluster strategies globally (Silicon Valley, Route 128, Shenzhen) but with heavy state coordination.

💼 Commercial Traction: From Lab to Market

The $5.6 million in confirmed orders represents more than revenue — it validates that neutral-atom quantum computing can transition from research to commercial deployment. Here’s what we know about the early adopters:

China Mobile Subsidiary: Telecommunications Applications

The first commercial Hanyuan-1 unit was delivered to a subsidiary of China Mobile, one of the world’s largest telecommunications operators. Whilst specific use cases weren’t disclosed, potential applications include:

• Network optimisation: Routing and traffic management across massive telecommunications infrastructure
• Quantum cryptography: Integration with China Mobile’s quantum communication initiatives
• Resource allocation: Optimising base station placement and spectrum utilisation
• Financial modeling: China Mobile has extensive fintech operations requiring complex calculations

China Mobile announced in October 2025 a major quantum technology initiative, making the Hanyuan No. 1 purchase part of a broader quantum computing and communication strategy.

Pakistan: International Expansion

Pakistan placed an order for Hanyuan No. 1 as part of a broader Memorandum of Understanding (MoU) signed in October 2025 to collaborate on quantum technologies under the China-Pakistan Economic Corridor’s second phase.

The Pakistan quantum partnership includes:

• National Center for Quantum Computing: China will assist Pakistan in establishing its first quantum computing facility
• Technology transfer: Knowledge sharing in quantum computing and quantum communication
• Research collaboration: Joint quantum technology development projects
• Training programmes: Developing Pakistan’s quantum workforce

Visual map showing confirmed deployments: China Mobile subsidiary (telecommunications sector, domestic), Pakistan National Center for Quantum Computing (international collaboration), and the under-construction Hubei quantum computing power centre (enterprise services). Geographic reach demonstrates commercial strategy.

Applications in Development

According to Hubei Daily, the system can handle complex applications in:

• Financial modeling: Risk analysis, portfolio optimisation, derivative pricing
• Logistics optimisation: Supply chain routing, warehouse management, delivery scheduling
• Industrial systems modeling: Manufacturing process optimisation
• Materials research: Future applications in materials design and drug discovery

More than 50 universities and companies have reportedly joined the project to explore quantum applications, suggesting an ecosystem is forming around the technology.

🌐 The Quantum Computing Power Centre: Building Infrastructure

Beyond selling individual systems, the Hanyuan project team is constructing China’s first neutral-atom quantum computing power centre — a facility designed to provide continuous quantum computing services to enterprise clients.

The Quantum-as-a-Service Model

The planned facility represents a shift toward “quantum-as-a-service” (QaaS) — similar to cloud computing models where users access quantum processors remotely rather than purchasing and operating their own systems.

Planned capabilities include:

• 24/7 quantum computing services: Continuous availability for enterprise workloads
• Clustered quantum processors: Multiple Hanyuan systems working in parallel
• Cloud-based interface: Users can design and test quantum algorithms without specialised physics knowledge
• Visual programming tools: Simplified quantum algorithm development
• Hardware optimisation: Automatic tuning for specific problem types
• Large-scale simulation: Hybrid classical-quantum computing approaches

The centre is expected to serve more than 1,000 enterprise clients annually, focusing on computationally demanding problems like financial risk analysis and industrial system modeling.

Competing with IBM and Amazon

This infrastructure strategy positions Hanyuan directly against established quantum cloud services:

• IBM Quantum Network: Cloud access to superconducting quantum processors
• Amazon Braket: Multi-vendor quantum computing service
• Microsoft Azure Quantum: Hybrid quantum-classical cloud platform
• Google Quantum AI: Research partnerships and enterprise access

The room-temperature operation and lower energy costs could give Hanyuan a competitive advantage in operating costs, though technical performance comparisons remain limited.

📈 Global Quantum Computing Race: 2025-2030 Outlook

Hanyuan No. 1’s commercial debut occurs against the backdrop of accelerating global quantum computing competition. Here’s how the landscape is evolving:

Key Market Predictions:

• Neutral-atom market share: Could capture 20-30% of quantum computing market by 2030 if scalability challenges are solved
• China’s quantum industry: Projected to be world’s second-largest quantum economy after US by 2030
• Quantum-as-a-service revenue: Expected to exceed $5 billion annually by 2030
• Pakistan and developing nations: Become early adopters through technology partnerships, potentially creating new quantum computing hubs

❓ Frequently Asked Questions