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Combining quantum error correction with sensing techniques to improve precision and robustness in quantum measurements.
This work investigates how quantum error correction (QEC) can enhance quantum sensing by protecting fragile quantum states from noise during measurement processes. The authors show that properly designed QEC codes can extend coherence times and improve sensitivity beyond standard limits. The framework bridges quantum computing and metrology, demonstrating that error-corrected sensors can maintain high precision even in noisy environments. This opens pathways for practical applications in fields like imaging, navigation, and fundamental physics experiments.