Abstract
We present a divide-and-conquer approach to deterministically prepare Dicke states |D<sub>k</sub><sup>n</sup>> (i.e. equal-weight superpositions of all n-qubit states with Hamming Weight k) on quantum computers. In an experimental evaluation for up to n=6 qubits on IBM Quantum Sydney and Montreal devices, we achieve significantly higher state fidelity compared to previous results [Mukherjee et.al. TQE'2020, Cruz et.al. QuTe'2019]. The fidelity gains are achieved through several techniques: Our circuits first divide the Hamming weight between blocks of n/2 qubits, and then conquer those blocks with improved versions of Dicke state unitaries [Brtschi et.al. FCT'2019]. Due to the sparse connectivity on IBM's heavy-hex-architectures, these circuits are implemented for linear nearest neighbor topologies. Further gains in (estimating) the state fidelity are due to our use of measurement error mitigation and hardware progress.
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