A lower bound on the overhead of quantum error correction in low dimensions
Abstract
We show that a quantum architecture with an error correction procedure limited to geometrically local operations incurs an overhead that grows with the system size, even if arbitrary error-free classical computation is allowed. In particular, we prove that in order to operate a quantum error correcting code in 2D at a logical error rate of δ, a space overhead of ((1/δ)) is needed for any constant depolarizing noise p > 0.
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