First heterogeneous quantum-classical computation on FLiBe clusters for tritium binding using EWF partitioning and ext-SQD on IBM hardware matches FCI fragment energies within 0.3 kcal/mol MAD but shows 12-110 kcal/mol errors in conformational and binding differences due to fragment construction.
Pascuzzi, Zhihao Xu, Tengfei Luo, Eungkyu Lee, and In-Saeng Suh
8 Pith papers cite this work. Polarity classification is still indexing.
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This paper presents a new open-source distributed QAOA simulator for QUBO problems that includes variable allocation across QPUs, runtime optimizations, a Streamlit GUI, and demonstrations of consistent results with monolithic QAOA on benchmarks and a power unit commitment application.
QESTO is a distributed variational ansatz using persistent Bell pairs for amplitude transfer in graph-based discrete optimization, showing stronger convergence than partitioned QAOA on Wang tile ensembles.
Three scheduling strategies for hybrid quantum-HPC systems cut classical resource use by up to 64% or boost QPU utilization depending on workload balance, validated on real hardware.
The authors present Pilot-Quantum, a middleware for adaptive resource management in hybrid quantum-HPC systems, along with execution motifs and a performance modeling toolkit called Q-Dreamer.
Parallel HADOF execution on up to four IBM QPUs achieves 3-4x wall-clock speedup for combinatorial QUBO problems versus sequential runs, with comparable quality and validation on genome assembly instances.
This thesis explores geometric and dynamical properties of entanglement in two- and many-body spin systems under XXZ and Ising interactions using phase space and Fubini-Study geometry.
A synthesis of expert insights from the ADAC Quantum Computing Working Group and member survey on the complementary roles of quantum and classical high-performance computing in future hybrid infrastructures.
citing papers explorer
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Quantum Computations on Fusion Blanket Molten Salts
First heterogeneous quantum-classical computation on FLiBe clusters for tritium binding using EWF partitioning and ext-SQD on IBM hardware matches FCI fragment energies within 0.3 kcal/mol MAD but shows 12-110 kcal/mol errors in conformational and binding differences due to fragment construction.
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Distributed Variational Quantum Optimisation by Entanglement-Selective Transport
QESTO is a distributed variational ansatz using persistent Bell pairs for amplitude transfer in graph-based discrete optimization, showing stronger convergence than partitioned QAOA on Wang tile ensembles.
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Three ways to share a QPU: Scheduling strategies for hybrid Quantum-HPC applications
Three scheduling strategies for hybrid quantum-HPC systems cut classical resource use by up to 64% or boost QPU utilization depending on workload balance, validated on real hardware.
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Hybrid Quantum-HPC Middleware Systems for Adaptive Resource, Workload and Task Management
The authors present Pilot-Quantum, a middleware for adaptive resource management in hybrid quantum-HPC systems, along with execution motifs and a performance modeling toolkit called Q-Dreamer.
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Towards High Performance Quantum Computing (HPQ): Parallelisation of the Hamiltonian Auto Decomposition Optimisation Framework (HADOF)
Parallel HADOF execution on up to four IBM QPUs achieves 3-4x wall-clock speedup for combinatorial QUBO problems versus sequential runs, with comparable quality and validation on genome assembly instances.
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Exploring the Geometric and Dynamical Properties of Spin Systems and Their Interplay with Quantum Entanglement
This thesis explores geometric and dynamical properties of entanglement in two- and many-body spin systems under XXZ and Ising interactions using phase space and Fubini-Study geometry.
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The Role of Quantum Computing in Advancing Scientific High-Performance Computing: A perspective from the ADAC Institute
A synthesis of expert insights from the ADAC Quantum Computing Working Group and member survey on the complementary roles of quantum and classical high-performance computing in future hybrid infrastructures.