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362 results on '"Rahm, Martin"'

1. Towards Efficient Quantum Computing for Quantum Chemistry: Reducing Circuit Complexity with Transcorrelated and Adaptive Ansatz Techniques

Author

Magnusson, Erika, Fitzpatrick, Aaron, Knecht, Stefan, Rahm, Martin, and Dobrautz, Werner

Subjects
Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Physics - Chemical Physics, Physics - Computational Physics
Abstract

The near-term utility of quantum computers is hindered by hardware constraints in the form of noise. One path to achieving noise resilience in hybrid quantum algorithms is to decrease the required circuit depth -- the number of applied gates -- to solve a given problem. This work demonstrates how to reduce circuit depth by combining the transcorrelated (TC) approach with adaptive quantum ans\"atze and their implementations in the context of variational quantum imaginary time evolution (AVQITE). The combined TC-AVQITE method is used to calculate ground state energies across the potential energy surfaces of H$_4$, LiH, and H$_2$O. In particular, H$_4$ is a notoriously difficult case where unitary coupled cluster theory, including singles and doubles excitations, fails to provide accurate results. Adding TC yields energies close to the complete basis set (CBS) limit while reducing the number of necessary operators -- and thus circuit depth -- in the adaptive ans\"atze. The reduced circuit depth furthermore makes our algorithm more noise-resilient and accelerates convergence. Our study demonstrates that combining the TC method with adaptive ans\"atze yields compact, noise-resilient, and easy-to-optimize quantum circuits that yield accurate quantum chemistry results close to the CBS limit.

Published
2024
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2. Ab Initio Transcorrelated Method enabling accurate Quantum Chemistry on near-term Quantum Hardware

Author

Dobrautz, Werner, Sokolov, Igor O., Liao, Ke, Ríos, Pablo López, Rahm, Martin, Alavi, Ali, and Tavernelli, Ivano

Subjects
Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Physics - Chemical Physics, Physics - Computational Physics
Abstract

Quantum computing is emerging as a new computational paradigm with the potential to transform several research fields, including quantum chemistry. However, current hardware limitations (including limited coherence times, gate infidelities, and limited connectivity) hamper the straightforward implementation of most quantum algorithms and call for more noise-resilient solutions. In quantum chemistry, the limited number of available qubits and gate operations is particularly restrictive since, for each molecular orbital, one needs, in general, two qubits. In this study, we propose an explicitly correlated Ansatz based on the transcorrelated (TC) approach, which transfers -- without any approximation -- correlation from the wavefunction directly into the Hamiltonian, thus reducing the number of resources needed to achieve accurate results with noisy, near-term quantum devices. In particular, we show that the exact transcorrelated approach not only allows for more shallow circuits but also improves the convergence towards the so-called basis set limit, providing energies within chemical accuracy to experiment with smaller basis sets and, therefore, fewer qubits. We demonstrate our method by computing bond lengths, dissociation energies, and vibrational frequencies close to experimental results for the hydrogen dimer and lithium hydride using just 4 and 6 qubits, respectively. Conventional methods require at least ten times more qubits for the same accuracy.

Published
2023

3. Reference-State Error Mitigation: A Strategy for High Accuracy Quantum Computation of Chemistry

Author

Lolur, Phalgun, Skogh, Mårten, Warren, Christopher, Biznárová, Janka, Osman, Amr, Tancredi, Giovanna, Wendin, Göran, Bylander, Jonas, and Rahm, Martin

Subjects
Quantum Physics, Physics - Computational Physics
Abstract

Decoherence and gate errors severely limit the capabilities of state-of-the-art quantum computers. This work introduces a strategy for reference-state error mitigation (REM) of quantum chemistry that can be straightforwardly implemented on current and near-term devices. REM can be applied alongside existing mitigation procedures, while requiring minimal post-processing and only one or no additional measurements. The approach is agnostic to the underlying quantum mechanical ansatz and is designed for the variational quantum eigensolver (VQE). Two orders-of-magnitude improvement in the computational accuracy of ground state energies of small molecules (H2, HeH+ and LiH) is demonstrated on superconducting quantum hardware. Simulations of noisy circuits with a depth exceeding 1000 two-qubit gates are used to argue for scalability of the method., Comment: Main manuscript: 12 pages, 3 figures. Attached supporting information: 21 pages, 8 figures

Published
2022

6. Contributors

Author

Akbarov, Khamdam, primary, Astudillo-Sánchez, P.D., additional, Ayarde-Henríquez, Leandro, additional, Berdimurodov, Elyor, additional, Bozkaya, Uğur, additional, Carbó-Dorca, Ramon, additional, Cárdenas, C., additional, Cedillo, Andrés, additional, Chakraborty, Tanmoy, additional, Chamorro, Eduardo, additional, Corzo, Héctor Hernández, additional, Díaz-Tinoco, Manuel, additional, Duque-Noreña, Mario, additional, Durán, Rocío, additional, Flores-Moreno, R., additional, Flores-Ramos, J.A., additional, Francisco, Evelio, additional, Freindorf, Marek, additional, Fuentealba, P., additional, Gallegos, Miguel, additional, Guerra, Cristian, additional, Guo, Lei, additional, Kaya, Savaş, additional, Kholikov, Abduvali, additional, Komorowski, Ludwik, additional, Kraka, Elfi, additional, Matute, Ricardo A., additional, Nagy, Á., additional, Nalewajski, Roman F., additional, Ordon, Piotr, additional, Ortega, Daniela E., additional, Ortiz, J.V., additional, Pawłowski, Filip, additional, Pendás, Ángel Martín, additional, Pérez, Patricia, additional, Rahm, Martin, additional, Rincón, Elizabeth, additional, Valdez-Ruvalcaba, J., additional, Villegas-Escobar, Nery, additional, von Szentpály, László, additional, Wang, Emily Z., additional, and Wang, Yi-Gui, additional

Published
2023
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9. Analytical calculation of pressure for confined atomic and molecular systems using the eXtreme-Pressure Polarizable Continuum Model

Author

Cammi, Roberto, Chen, Bo, and Rahm, Martin

Subjects
Physics - Chemical Physics
Abstract

We show that the pressure acting on atoms and molecular systems within the compression cavity of the eXtreme-Pressure Polarizable Continuum method can be expressed in terms of the electron density of the systems and of the Pauli-repulsion confining potential. The analytical expression holds for spherical cavities as well as for cavities constructed from van der Waals spheres of the constituting atoms of the molecular systems.

Published
2018

25. Rocket Scientist for a Day: Investigating Alternatives for Chemical Propulsion

Author

Angelin, Marcus, Rahm, Martin, and Gabrielsson, Erik

Abstract

This laboratory experiment introduces rocket science from a chemistry perspective. The focus is set on chemical propulsion, including its environmental impact and future development. By combining lecture-based teaching with practical, theoretical, and computational exercises, the students get to evaluate different propellant alternatives. To complete the task, they need to use several important curricular concepts, such as the breaking and formation of bonds, redox reactions, and thermodynamics. They also apply basic computational electronic structure calculations to investigate the energetic content of hitherto nonexisting alternatives. Finally, actual chemical rocket propulsion is demonstrated through the assembly and testing of a model rocket motor, employing a commercially available kit. The full experiment was developed for upper-level high school classes and is completed in a 3-h lab period. The experiment, or parts of it, has also been successfully used both in undergraduate programs and continuing education for teachers. (Contains 3 figures.)

Published
2012
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31. Electronegativity at the Shock Front.

Author

Rahm, Martin

Subjects
SHOCK waves, EXCITED states, NITROMETHANE, CHEMICAL bonds, ELECTRONEGATIVITY
Abstract

In this work, a scale for pressure‐adapted atomic electronegativity is used to make general predictions of bond polarity in H‐, C‐, N‐ and O‐based compounds experiencing shock conditions. The qualitative picture that emerges is one of increasing polarity of several bonds common in energetic materials. The general predictions made are compared to, and found to support, claims of ionic decomposition routes in compressed nitromethane and nitrate esters at high pressure. Changing electronegativity is also suggested as a factor driving the ionic disproportionation of various molecular phases with compression. Calculations using the eXtreme‐Pressure Polarizable Continuum Model (XP‐PCM) predict increasing energy differences between ground and excited states in non‐bonded H, C, N, and O atoms as a function of pressure. This data enables for a discussion on the reliability of electronegativity‐based rationales at more extreme thermodynamic conditions. [ABSTRACT FROM AUTHOR]

Published
2023
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38. DBU-Catalyzed Ring-Opening and Retro-Claisen Fragmentation of Dihydropyranones

Author

Axelsson, Anton, Hammarvid, Emmelie, Rahm, Martin, Sundén, Henrik, Axelsson, Anton, Hammarvid, Emmelie, Rahm, Martin, and Sundén, Henrik

Abstract

We present a general protocol for the formal Michael addition of acetone to alpha,beta-unsaturated esters and amides, a transformation difficult to perform using current methods. The protocol comprises of an amidine catalyzed relay ring-opening and fragmentation of 3,4-dihydropyranones. The reaction proceeds under mild conditions, has a broad substrate scope and the products can be isolated in good to excellent yields. The method can be applied to homochiral substrates with total preservation of chiral information, generating products in high optical purity. Kinetic experiments supported by quantum chemical modeling indicate a mechanism in which the catalyst takes a bifunctional role, acting both as a Bronsted base and as a hydrogen-bond donor., QC 20211014

Published
2020
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49. Nine questions on energy decomposition analysis

Author

Andrés, Juan, primary, Ayers, Paul W., additional, Boto, Roberto A., additional, Carbó‐Dorca, Ramon, additional, Chermette, Henry, additional, Cioslowski, Jerzy, additional, Contreras‐García, Julia, additional, Cooper, David L., additional, Frenking, Gernot, additional, Gatti, Carlo, additional, Heidar‐Zadeh, Farnaz, additional, Joubert, Laurent, additional, Martín Pendás, Ángel, additional, Matito, Eduard, additional, Mayer, István, additional, Misquitta, Alston J., additional, Mo, Yirong, additional, Pilmé, Julien, additional, Popelier, Paul L. A., additional, Rahm, Martin, additional, Ramos‐Cordoba, Eloy, additional, Salvador, Pedro, additional, Schwarz, W. H. Eugen, additional, Shahbazian, Shant, additional, Silvi, Bernard, additional, Solà, Miquel, additional, Szalewicz, Krzysztof, additional, Tognetti, Vincent, additional, Weinhold, Frank, additional, and Zins, Émilie‐Laure, additional

Published
2019
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