# Machine Learning the Decoherence Property of Superconducting and Semiconductor Quantum Devices from Graph Connectivity

**Authors:** Quan Fu, Jie Liu, Xin Wang, Rui Xiong

PMC · DOI: 10.3390/e28010089 · 2026-01-12

## TL;DR

This paper uses machine learning to predict how long quantum devices can maintain coherence based on their connectivity patterns.

## Contribution

A novel machine learning framework that predicts decoherence lifetimes from graph connectivity in quantum devices.

## Key findings

- The model achieves R2>0.96 for predicting decoherence lifetimes in both superconducting and semiconductor platforms.
- Superconducting qubits are more sensitive to global connectivity measures, while semiconductor qubits depend heavily on system scale.
- Cross-platform model transfer fails completely, showing the need for platform-specific design strategies.

## Abstract

Quantum computing faces significant challenges from decoherence and noise, which limit the practical implementation of quantum algorithms. While substantial progress has been made in improving individual qubit coherence times, the collective behavior of interconnected qubit systems remains incompletely understood. The connectivity architecture plays a crucial role in determining overall system susceptibility to environmental noise, yet systematic characterization of this relationship has been hindered by computational complexity. We develop a machine learning framework that bridges graph features with quantum device characterization to predict decoherence lifetime directly from connectivity patterns. By representing quantum architectures as connected graphs and using 14 topological features as input to supervised learning models, we achieve accurate lifetime predictions with R2>0.96 for both superconducting and semiconductor platforms. Our analysis reveals fundamentally distinct decoherence mechanisms: superconducting qubits show high sensitivity to global connectivity measures (betweenness centrality δ1=0.484, spectral entropy δ1=0.480), while semiconductor quantum dots exhibit exceptional sensitivity to system scale (node count δ2=0.919, importance = 1.860). The complete failure of cross-platform model transfer (R2 scores of −0.39 and −433.60) emphasizes the platform-specific nature of optimal connectivity design. Our approach enables rapid assessment of quantum architectures without expensive simulations, providing practical guidance for noise-optimized quantum processor design.

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12840289/full.md

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Source: https://tomesphere.com/paper/PMC12840289