Fault-Tolerant Preparation of Quantum Polar Codes Encoding One Logical Qubit

Abstract

This paper explores a new approach to fault-tolerant quantum computing (FTQC), relying on quantum polar codes. We consider quantum polar codes of Calderbank-Shor-Steane type, encoding one logical qubit, which we refer to as Q1 codes. First, we show that a subfamily of Q1 codes is equivalent to the well-known family of Shor codes. Moreover, we show that Q1 codes significantly outperform Shor codes, of the same length and minimum distance. Second, we consider the fault-tolerant preparation of Q1 code states. We give a recursive procedure to prepare a Q1 code state, based on two-qubit Pauli measurements only. The procedure is not by itself fault-tolerant, however, the measurement operations therein provide redundant classical bits, which can be advantageously used for error detection. Fault-tolerance is then achieved by combining the proposed recursive procedure with an error detection method. Finally, we consider the fault-tolerant error correction of Q1 codes. We use Steane error correction, which incorporates the proposed fault-tolerant code state preparation procedure. We provide numerical estimates of the logical error rates for Q1 and Shor codes of length 16 and 64 qubits, assuming a circuit-level depolarizing noise model. Remarkably, the Q1 code of length 64 qubits achieves a logical error rate very close to 10-6 for the physical error rate p = 10-3, therefore, demonstrating the potential of the proposed polar codes based approach to FTQC.