Your search keyword '"Buda, Corneliu"' showing total 6 results

1. Experimental demonstration of Robust Amplitude Estimation on near-term quantum devices for chemistry applications

Author

Kunitsa, Alexander, Bellonzi, Nicole, Guo, Shangjie, Gonthier, Jérôme F., Buda, Corneliu, Abuan, Clena M., and Romero, Jhonathan

Subjects

Quantum Physics

Abstract

This study explores hardware implementation of Robust Amplitude Estimation (RAE) on IBM quantum devices, demonstrating its application in quantum chemistry for one- and two-qubit Hamiltonian systems. Known for potentially offering quadratic speedups over traditional methods in estimating expectation values, RAE is evaluated under realistic noisy conditions. Our experiments provide detailed insights into the practical challenges associated with RAE. We achieved a significant reduction in sampling requirements compared to direct measurement techniques. In estimating the ground state energy of the hydrogen molecule, the RAE implementation demonstrated two orders of magnitude better accuracy for the two-qubit experiments and achieved chemical accuracy. These findings reveal its potential to enhance computational efficiencies in quantum chemistry applications despite the inherent limitations posed by hardware noise. We also found that its performance can be adversely impacted by coherent error and device stability and does not always correlate with the average gate error. These results underscore the importance of adapting quantum computational methods to hardware specifics to realize their full potential in practical scenarios.

Published

2024

2. A dual-cutoff machine-learned potential for condensed organic systems obtained via uncertainty-guided active learning

Author

Kahle, Leonid, Minisini, Benoit, Bui, Tai, First, Jeremy T., Buda, Corneliu, Goldman, Thomas, and Wimmer, Erich

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science

Abstract

Machine-learned potentials (MLPs) trained on ab initio data combine the computational efficiency of classical interatomic potentials with the accuracy and generality of the first-principles method used in the creation of the respective training set. In this work, we implement and train a MLP to obtain an accurate description of the potential energy surface and property predictions for organic compounds, as both single molecules and in the condensed phase. We devise a dual descriptor, based on the atomic cluster expansion (ACE), that couples an information-rich short-range description with a coarser long-range description that captures weak intermolecular interactions. We employ uncertainty-guided active learning for the training set generation, creating a dataset that is comparatively small for the breadth of application and consists of alcohols, alkanes, and an adipate. Utilizing that MLP, we calculate densities of those systems of varying chain lengths as a function of temperature, obtaining a discrepancy of less than 4% compared with experiment. Vibrational frequencies calculated with the MLP have a root mean square error of less than 1 THz compared to DFT. The heat capacities of condensed systems are within 11% of experimental findings, which is strong evidence that the dual descriptor provides an accurate framework for the prediction of both short-range intramolecular and long-range intermolecular interactions.

Published

2024

3. Diffusion Mechanisms and Preferential Dynamics of Promoter Molecules in ZSM-5 Zeolite

Author

Dunn, Josh, primary, Crossley-Lewis, Joe, additional, McCluskey, Andrew, additional, Jackson, Fiona, additional, Buda, Corneliu, additional, Sunley, Glenn, additional, Mulholland, Adrian, additional, and Allan, Neil, additional

Published

2024

4. Diffusion mechanisms and preferential dynamics of promoter molecules in ZSM-5 zeolite.

Author

Dunn, Josh, Crossley-Lewis, Joe, McCluskey, Andrew R., Jackson, Fiona, Buda, Corneliu, Sunley, Glenn J., Mulholland, Adrian J., and Allan, Neil L.

Published

2024

5. Multilevel quantum mechanical calculations show the role of promoter molecules in the dehydration of methanol to dimethyl ether in H-ZSM-5.

Author

Crossley-Lewis, Joe, Dunn, Josh, Hickman, Isabel F., Jackson, Fiona, Sunley, Glenn J., Buda, Corneliu, Mulholland, Adrian J., and Allan, Neil L.

Abstract

Methyl carboxylate esters promote the formation of dimethyl ether (DME) from the dehydration of methanol in H-ZSM-5 zeolite. We employ a multilevel quantum method to explore the possible associative and dissociative mechanisms in the presence, and absence, of six methyl ester promoters. This hybrid method combines density functional theory, with dispersion corrections (DFT-D3), for the full periodic system, with second-order Møller–Plesset perturbation theory (MP2) for small clusters representing the reaction site, and coupled cluster with single, double, and perturbative triple substitution (CCSD(T)) for the reacting molecules. The calculated adsorption enthalpy of methanol, and reaction enthalpies of the dehydration of methanol to DME within H-ZSM-5, agree with experiment to within chemical accuracy (∼4 kJ mol−1). For the promoters, a reaction pathway via an associative mechanism gives lower overall reaction enthalpies and barriers compared to the reaction with methanol only. Each stage of this mechanism is explored and related to experimental data. We provide evidence that suggests the promoter's adsorption to the Brønsted acid site is the most important factor dictating its efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

6. A dual-cutoff machine-learned potential for condensed organic systems obtained via uncertainty-guided active learning.

Author

Kahle L, Minisini B, Bui T, First JT, Buda C, Goldman T, and Wimmer E

Abstract

Machine-learned potentials (MLPs) trained on ab initio data combine the computational efficiency of classical interatomic potentials with the accuracy and generality of the first-principles method used in the creation of the respective training set. In this work, we implement and train a MLP to obtain an accurate description of the potential energy surface and property predictions for organic compounds, as both single molecules and in the condensed phase. We devise a dual descriptor, based on the atomic cluster expansion (ACE), that couples an information-rich short-range description with a coarser long-range description that captures weak intermolecular interactions. We employ uncertainty-guided active learning for the training set generation, creating a dataset that is comparatively small for the breadth of application and consists of alcohols, alkanes, and an adipate. Utilizing that MLP, we calculate densities of those systems of varying chain lengths as a function of temperature, obtaining a discrepancy of less than 4% compared with experiment. Vibrational frequencies calculated with the MLP have a root mean square error of less than 1 THz compared to DFT. The heat capacities of condensed systems are within 11% of experimental findings, which is strong evidence that the dual descriptor provides an accurate framework for the prediction of both short-range intramolecular and long-range intermolecular interactions.

Published

2024