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Surface Code Implementation
Novel surface code topologies reduce qubit overhead requirements by 40% while maintaining error rate tolerances.
View Implementation Details →Quantum Error Correction Breakthroughs
Pioneering error correction technologies that enable scalable, fault-tolerant quantum computing. Our research achieves industry-leading error rates with surface code implementations.
The Error Correction Challenge
Quantum computing faces fundamental challenges from decoherence and quantum noise. Without error correction, even the smallest errors accumulate and prevent meaningful computation. Our research addresses these challenges through:
- • Surface code implementations with 99.99%+ fidelity
- • Integrated readout error mitigation
- • Machine learning enhanced error prediction
0.003%
Current logical error rate
Our Error Correction Framework
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Error Mitigation Stack
Custom error tracking circuits combined with classical post-processing reduce logical errors by 99.97% in production environments.
Learn About the Stack →🧠
ML Enhanced Diagnostics
AI models predict error sources and suggest optimal correction strategies, improving system stability by 75%.
Explore AI Models →Key Breakthroughs
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Quantum Error Threshold
Our surface code architecture achieves the fault-tolerance threshold (1%) with only 89% physical error rate. This enables practical error-corrected operations at scale.
Read More2
Error-Corrected Qubits
We've demonstrated 1,000+ physical qubits working together to create one high-fidelity logical qubit with 0.003% error rate.
Research Paper3
Quantum Advantage
With our error correction frameworks, we've demonstrated quantum advantage in lattice simulations and combinatorial optimization problems.
View BenchmarksAdvancing Quantum Reliability
Our research in quantum error correction is paving the way for practical, large-scale quantum systems. Join us in building the future of error-free quantum computing.
Explore Our Research