Related papers: Benchmarking the Impact of Active Space Selection on the VQE Pipeline for Quantum Drug Discovery

Benchmarking the Impact of Active Space Selection on the VQE Pipeline for Quantum Drug Discovery

URL: http://arxiv.org/abs/2512.18203v1
Date: Sat, 20 Dec 2025 03:56:12 GMT
Title: Benchmarking the Impact of Active Space Selection on the VQE Pipeline for Quantum Drug Discovery
Authors: Zhi Yin, Xiaoran Li, Zhupeng Han, Shengyu Zhang, Xin Li, Zhihong Zhang, Runqing Zhang, Anbang Wang, Xiaojin Zhang,
Abstract summary: Quantum computers promise scalable treatments of electronic structure.<n>Applying variational quantum eigensolvers (VQE) on realistic drug-like molecules remains constrained by the performance limitations of near-term quantum hardwares.<n>This work establishes the first systematic benchmark for active space driven VQE and lays the groundwork for future hardware-algorithm co-design studies in quantum drug discovery.
Score: 14.312202507766463
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum computers promise scalable treatments of electronic structure, yet applying variational quantum eigensolvers (VQE) on realistic drug-like molecules remains constrained by the performance limitations of near-term quantum hardwares. A key strategy for addressing this challenge which effectively leverages current Noisy Intermediate-Scale Quantum (NISQ) hardwares yet remains under-benchmarked is active space selection. We introduce a benchmark that heuristically proposes criteria based on chemically grounded metrics to classify the suitability of a molecule for using quantum computing and then quantifies the impact of active space choices across the VQE pipeline for quantum drug discovery. The suite covers several representative drug-like molecules (e.g., lovastatin, oseltamivir, morphine) and uses chemically motivated active spaces. Our VQE evaluations employ both simulation and quantum processing unit (QPU) execution using unitary coupled-cluster with singles and doubles (UCCSD) and hardware-efficient ansatz (HEA). We adopt a more comprehensive evaluation, including chemistry metrics and architecture-centric metrics. For accuracy, we compare them with classical quantum chemistry methods. This work establishes the first systematic benchmark for active space driven VQE and lays the groundwork for future hardware-algorithm co-design studies in quantum drug discovery.

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