Quantum Hardware Progress: The Race to CRQC

Latest Hardware: Condor (2023)

• Physical qubits: 1,121
• Logical qubits: Not yet achieved at scale
• Error rate: ~10^-3 (0.1% per gate operation)
• Significance: First to break 1,000 qubit barrier

Roadmap

• 2025: 4,000+ qubit systems (still physical)
• 2026-2027: Focus shifts to error correction and logical qubits
• 2029-2030: Target 100+ logical qubits (IBM’s published goal)

Crypto Implications

IBM is following a “scale up physical qubits first, then improve error correction” strategy. Progress is steady but incremental. If they hit their 2030 target (100 logical qubits), they’ll still be ~15× short of CRQC, but the trajectory would suggest CRQC by 2033-2035.

Latest Hardware: Willow (2024)

• Physical qubits: 105
• Logical qubits: Demonstrated error rates below threshold for quantum error correction
• Error rate: Below 10^-3, approaching the threshold needed for scalable error correction
• Significance: Quality over quantity—proves error correction is feasible

Key Achievement

Willow demonstrated that adding more physical qubits for error correction reduces errors rather than amplifying them (a critical milestone called “below threshold”). This proves the path to logical qubits works in practice, not just theory.

Roadmap

• Google publishes less detailed roadmaps than IBM
• Focus appears to be on error correction quality first, scaling second
• If they can maintain below-threshold error rates while scaling, they could leap ahead

Crypto Implications

Google’s approach (perfect the error correction, then scale) could lead to faster progress once they start scaling. Willow’s breakthrough suggests Google might reach 100+ logical qubits sooner than IBM’s timeline. Watch Google closely.

Latest Hardware: IonQ Forte (2024)

• Physical qubits: 32 (smaller than superconducting competitors)
• Algorithmic qubits: ~29 (IonQ’s metric for “useful qubits”)
• Error rate: ~10^-4 (better than superconducting qubits)
• Significance: Higher quality qubits, fewer in number

Trapped Ion Advantages

• Better connectivity: Any qubit can interact with any other (vs. limited connectivity in superconducting)
• Lower error rates: Ions are more stable than superconducting circuits
• Longer coherence times: Can perform more operations before decoherence

Crypto Implications

IonQ’s approach (high-quality, low-quantity) means they might reach logical qubits with fewer physical qubits than IBM or Google. However, scaling to 1,500 logical qubits could take longer. Less immediate threat than superconducting approaches, but don’t discount them.

Known Progress

• Physical qubits: 100+ (estimated, some programs classified)
• Approaches: Superconducting, photonic, trapped ion
• Funding: Massive government investment (exact figures undisclosed)
• Transparency: Limited—some achievements published, many likely classified

Key Milestones

• 2020: Jiuzhang photonic quantum computer claimed quantum advantage
• 2021: Zuchongzhi superconducting processor (66 qubits)
• 2023+: Reports of 100+ qubit systems, but details sparse

Crypto Implications

The unknown factor. If China achieves CRQC first, they may not announce it publicly. The NSA likely assumes China’s capabilities are more advanced than publicly disclosed. This is why “store now, decrypt later” attacks are already a concern—adversaries may be collecting encrypted crypto transactions today, betting on quantum decryption within 5-10 years.