Quantum Convolutional Neural Network for Phase Recognition in Two Dimensions
- URL: http://arxiv.org/abs/2407.04114v2
- Date: Thu, 18 Sep 2025 15:02:56 GMT
- Title: Quantum Convolutional Neural Network for Phase Recognition in Two Dimensions
- Authors: Leon C. Sander, Nathan A. McMahon, Petr Zapletal, Michael J. Hartmann,
- Abstract summary: Quantum convolutional neural networks (QCNNs) are quantum circuits for characterizing complex quantum states.<n>Here we construct a QCNN that can perform phase recognition in two dimensions.<n>The network also exhibits a noise threshold up to which the topological order is recognized.
- Score: 0.5219568203653523
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Quantum convolutional neural networks (QCNNs) are quantum circuits for characterizing complex quantum states. They have been proposed for recognizing quantum phases of matter at low sampling cost and have been designed for condensed matter systems in one dimension. Here we construct a QCNN that can perform phase recognition in two dimensions and correctly identify the phase transition from a Toric Code phase with $\mathbb{Z}_2$-topological order to the paramagnetic phase. The network also exhibits a noise threshold up to which the topological order is recognized. Furthermore, it captures correlations between all stabilizer elements of the Toric Code, which cannot be accessed by direct measurements. This increases the threshold for errors leading to such correlations and allows for correctly identifying the topological phase in the presence of strong correlated errors. Our work generalizes phase recognition with QCNNs to higher spatial dimensions and intrinsic topological order, where exploration and characterization via classical numerics become challenging.
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