To assess whether qubit flips were correlated, the researchers measured fluctuations in offset charge for all four qubits. The scientists cool the chip to nearly absolute zero, which makes it superconduct and protects it from error-causing interference from the outside environment.
The research team designed a chip with four qubits made of the superconducting elements niobium and aluminum. In this new study, they directly asked: are these flips independent, or are they correlated? In earlier experiments, McDermott’s group had seen hints that something was causing multiple qubits to flip at the same time.
However, the surface code protocol works reliably only if events that cause errors are isolated, affecting at most a few qubits. The surface code involves a large array of connected qubits – some do the computational work, while others are monitored to infer errors in the computational qubits. But the laws of quantum physics say that only one error type can be monitored at a time in a single qubit, so a clever error correction protocol called the surface code has been proposed. To fix errors, computers must monitor them as they happen. Qubits, however, can make two types of error: bit flips or phase flips, where a quantum superposition state changes. Classical bits, then, can only make bit flip errors, such as when a 1 flips to 0.
The bits in a classical computer can either be a 1 or a 0, but the qubits in a quantum computer can be 1, 0, or an arbitrary mixture – a superposition – of 1 and 0. “Our experiments show absolutely that errors are correlated, but as we identify problems and develop a deep physical understanding, we’re going to find ways to work around them.” “I think people have been approaching the problem of error correction in an overly optimistic way, blindly making the assumption that errors are not correlated,” says UW-Madison physics Professor Robert McDermott, senior author of the study.