An Army project devised a novel approach for quantum error correction that could provide a key step toward quantum computing that would enable the military to potentially solve previously intractable problems or deploy sensors with higher magnetic and electric field sensitivities. The approach, developed by researchers at Massachusetts Institute of Technology with Army funding, could mitigate certain types of the random fluctuations, or noise, that are a longstanding barrier to quantum computing. These random fluctuations can eradicate the data stored in such devices.
The work involves identifying the kinds of noise that are the most likely, rather than casting a broad net to try to catch all possible sources of disturbance. The overhead for certain types of error correction can be reduced on small-scale quantum systems, which has the potential to enable increased capabilities in targeted quantum information science applications for the DOD.
The specific quantum system the team is working with consists of carbon nuclei near a particular kind of defect in a diamond crystal called a nitrogen vacancy center. These defects behave like single, isolated electrons and their presence enables the control of the nearby carbon nuclei. But the overwhelming majority of the noise affecting these nuclei came from one single source: random fluctuations in the nearby defects themselves.
This noise source can be accurately modeled and suppressing its effects could have a major impact, as other sources of noise are relatively insignificant.
The team determined that the noise comes from one central defect, or one central electron that has a tendency to hop around at random — jittering. That jitter, in turn, is felt by all those nearby nuclei in a predictable way that can be corrected. The ability to apply this targeted correction in a successful way is the central breakthrough of this research.
If a demonstration works as expected, this research could make up an important component of near- and far-term future quantum-based technologies of various kinds including quantum computers and sensors.