Your search keyword '"Talarico, N. Walter"' showing total 6 results

1. Estimating molecular thermal averages with the quantum equation of motion and informationally complete measurements

Author

Morrone, Daniele, Talarico, N. Walter, Cattaneo, Marco, and Rossi, Matteo A. C.

Subjects

Quantum Physics

Abstract

By leveraging the Variational Quantum Eigensolver (VQE), the ``quantum equation of motion" (qEOM) method established itself as a promising tool for quantum chemistry on near term quantum computers, and has been used extensively to estimate molecular excited states. Here, we explore a novel application of this method, employing it to compute thermal averages of quantum systems, specifically molecules like ethylene and butadiene. A drawback of qEOM is that it requires measuring the expectation values of a large number of observables on the ground state of the system, and the number of necessary measurements can become a bottleneck of the method. In this work we focus on measurements through informationally complete positive operator-valued measures (IC-POVMs) to achieve a reduction in the measurements overheads. We show with numerical simulations that the qEOM combined with IC-POVM measurements ensures a satisfactory accuracy in the reconstruction of the thermal state with a reasonable number of shots., Comment: 7 pages, 9 figures

Published

2024

2. Quantum-centric strong and dynamical electron correlation: A resource-efficient second-order $N$-electron valence perturbation theory formulation for near-term quantum devices

Author

Fitzpatrick, Aaron, Talarico, N. Walter, Eikås, Roberto Di Remigio, and Knecht, Stefan

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

We present a measurement-cost efficient implementation of Strongly-Contracted $N$-Electron Valence Perturbation Theory (SC-NEVPT2) for use on near-term quantum devices. At the heart of our algorithm we exploit the properties of adaptive Informationally Complete positive operator valued measures (IC-POVMs) to recycle the measurement outcomes from a ground state energy estimation on a quantum device to reconstruct the matrix elements of the three- and four-body reduced density matrices for use in a subsequent CPU-driven NEVPT2 calculation. The proposed scheme is capable of producing results in good agreement with corresponding conventional NEVPT2 simulations, while significantly reducing the cost of quantum measurements and allowing for embarrassingly parallel estimations of higher-order RDMs in classical post-processing. Our scheme shows favourable scaling of the total number of shots with respect to system size. This paves the way for routine inclusion of dynamic electron correlation effects in hybrid quantum-classical computing pipelines., Comment: 12 pages, 6 figures

Published

2024

3. A self-consistent field approach for the variational quantum eigensolver: orbital optimization goes adaptive

Author

Fitzpatrick, Aaron, Nykänen, Anton, Talarico, N. Walter, Lunghi, Alessandro, Maniscalco, Sabrina, García-Pérez, Guillermo, and Knecht, Stefan

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

We present a self consistent field approach (SCF) within the Adaptive Derivative-Assembled Problem-Tailored Ansatz Variational Quantum Eigensolver (ADAPT-VQE) framework for efficient quantum simulations of chemical systems on near-term quantum computers. To this end, our ADAPT-VQE-SCF approach combines the idea of generating an ansatz with a small number of parameters, resulting in shallow-depth quantum circuits with a direct minimization of an energy expression which is correct to second order with respect to changes in the molecular orbital basis. Our numerical analysis, including calculations for the transition metal complex ferrocene (Fe$\rm (C_5H_5)_2$), indicates that convergence in the self-consistent orbital optimization loop can be reached without a considerable increase in the number of two-qubit gates in the quantum circuit by comparison to a VQE optimization in the initial molecular orbital basis. Moreover, the orbital optimization can be carried out simultaneously within each iteration of the ADAPT-VQE cycle. ADAPT-VQE-SCF thus allows us to implement a routine analogous to CASSCF, a cornerstone of state-of-the-art computational chemistry, in a hardware-efficient manner on near-term quantum computers. Hence, ADAPT-VQE-SCF paves the way towards a paradigm shift for quantitative quantum-chemistry simulations on quantum computers by requiring fewer qubits and opening up for the use of large and flexible atomic orbital basis sets in contrast to earlier methods that are predominantly based on the idea of full active spaces with minimal basis sets., Comment: 21 pages, 5 figures

Published

2022

4. Quantum network medicine: rethinking medicine with network science and quantum algorithms

Author

Maniscalco, Sabrina, Borrelli, Elsi-Mari, Cavalcanti, Daniel, Foti, Caterina, Glos, Adam, Goldsmith, Mark, Knecht, Stefan, Korhonen, Keijo, Malmi, Joonas, Nykänen, Anton, Rossi, Matteo A. C., Saarinen, Harto, Sokolov, Boris, Talarico, N. Walter, Westergren, Jussi, Zimborás, Zoltán, and García-Pérez, Guillermo

Subjects

Quantum Physics, Quantitative Biology - Molecular Networks, Quantitative Biology - Quantitative Methods

Abstract

Scientific and technological advances in medicine and systems biology have unequivocally shown that health and disease must be viewed in the context of the interplay among multiple molecular and environmental factors. Understanding the effects of cellular interconnection on disease progression may lead to the identification of novel disease genes and pathways, and hence influence precision diagnostics and therapeutics. To accomplish this goal, the emerging field of network medicine applies network science approaches to investigate disease pathogenesis, integrating information from relevant Omics databases, including protein-protein interaction, correlation-based, gene regulatory, and Bayesian networks. However, this requires analysing and computing large amounts of data. Moreover, if we are to efficiently search for new drugs and new drug combinations, there is a pressing need for computational methods that could allow us to access the immense chemical compound space until now largely unexplored. Finally, at the microscopic level, drug-target chemistry simulation is ultimately a quantum problem, and hence it requires a quantum solution. As we will discuss, quantum computing may be a key ingredient in enabling the full potential of network medicine. We propose to combine network medicine and quantum algorithms in a novel research field, quantum network medicine, to lay the foundations of a new era of disease prevention and drug design.

Published

2022

5. Entanglement Protection via Periodic Environment Resetting in Continuous Time Quantum Dynamical Processes

Author

Bullock, Thomas, Cosco, Francesco, Haddara, Marwan, Raja, Sina Hamedani, Kerppo, Oskari, Leppäjärvi, Leevi, Siltanen, Olli, Talarico, N. Walter, De Pasquale, Antonella, Giovannetti, Vittorio, and Maniscalco, Sabrina

Subjects

Quantum Physics

Abstract

The temporal evolution of entanglement between a noisy system and an ancillary system is analyzed in the context of continuous time open quantum system dynamics. Focusing on a couple of analytically solvable models for qubit systems, we study how Markovian and non-Markovian characteristics influence the problem, discussing in particular their associated entanglement-breaking regimes. These performances are compared with those one could achieve when the environment of the system is forced to return to its input configuration via periodic instantaneous resetting procedures., Comment: Published version, with corrected equations and improved figures

Published

2018

6. Entanglement Protection via Periodic Environment Resetting in Continuous Time Quantum Dynamical Processes

Author

Marwan Haddara, Oskari Kerppo, Sina Hamedani Raja, Leevi Leppäjärvi, Vittorio Giovannetti, N. Walter Talarico, Tom Bullock, Sabrina Maniscalco, Antonella De Pasquale, Olli Siltanen, Francesco Cosco, Bullock, Thoma, Cosco, Francesco, Haddara, Marwan, Raja, Sina Hamedani, Kerppo, Oskari, Leppäjärvi, Leevi, Siltanen, Olli, Talarico, N. Walter, De Pasquale, Antonella, Giovannetti, Vittorio, Maniscalco, Sabrina, University of Turku, University of Florence, CNR-ENEA-EURATOM Association, Centre of Excellence in Quantum Technology, QTF, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects

Physics, Quantum Physics, Time quantum, Quantum decoherence, ta114, Markov process, FOS: Physical sciences, Context (language use), Quantum entanglement, 01 natural sciences, canali entanglement breaking, correlazioni quantistiche, regime non markoviano, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, Settore FIS/03 - Fisica della Materia, Open quantum system, symbols.namesake, Qubit, 0103 physical sciences, symbols, Statistical physics, 010306 general physics, Error detection and correction, Quantum Physics (quant-ph)

Abstract

The temporal evolution of entanglement between a noisy system and an ancillary system is analyzed in the context of continuous time open quantum system dynamics. Focusing on a couple of analytically solvable models for qubit systems, we study how Markovian and non-Markovian characteristics influence the problem, discussing in particular their associated entanglement-breaking regimes. These performances are compared with those one could achieve when the environment of the system is forced to return to its input configuration via periodic instantaneous resetting procedures., Comment: Published version, with corrected equations and improved figures

Published

2018