Under CopyrightBentellis, AmineAmineBentellisMatic-Flierl, AndreaAndreaMatic-FlierlMendl, Christian B.Christian B.MendlLorenz, Jeanette MiriamJeanette MiriamLorenz2023-12-082023-12-082023https://publica.fraunhofer.de/handle/publica/457796https://doi.org/10.24406/h-45779610.1109/QCE57702.2023.0006510.24406/h-457796The Variational Quantum Eigensolver (VQE) is a promising quantum algorithm for applications in chemistry within the Noisy Intermediate-Scale Quantum (NISQ) era. The ability for a quantum computer to simulate electronic structures with high accuracy would have a profound impact on material and biochemical science with potential applications e.g., to the development of new drugs. However, considering the variety of quantum hardware architectures, it is still uncertain which hardware concept is most suited to execute the VQE for e.g., the simulation of molecules. Aspects to consider here are the required connectivity of the quantum circuit used, the size and the depth and thus the susceptibility to noise effects. Besides theo-retical considerations, empirical studies using available quantum hardware may help to clarify the question of which hardware technology might be better suited for a certain given application and algorithm. Going one step into this direction, within this work, we present results using the VQE for the simulation of the hydrogen molecule, comparing superconducting and ion trap quantum computers. The experiments are carried out with a standardized setup of ansatz and optimizer, selected to reduce the number of required iterations. The findings are analyzed considering different quantum processor types, calibration data as well as the depth and gate counts of the circuits required for the different hardware concepts after transpilation.enquantum computingVariational Quantum EigensolverVQEquantum hardware comparisonion trap quantum computersuperconduction quantum computerconference paper