Related papers: Computing excited states of molecules using normalizing flows

Computing excited states of molecules using normalizing flows

URL: http://arxiv.org/abs/2308.16468v2
Date: Mon, 11 Nov 2024 12:34:53 GMT
Title: Computing excited states of molecules using normalizing flows
Authors: Yahya Saleh, Álvaro Fernández Corral, Emil Vogt, Armin Iske, Jochen Küpper, Andrey Yachmenev,
Abstract summary: We introduce a new method that utilizes normalizing flows (parametrized invertible functions) to optimize vibrational coordinates to satisfy the variational principle. This approach produces coordinates specifically tailored to the vibrational problem at hand, significantly increasing the accuracy and enhancing basis set convergence. We demonstrate that the optimized coordinates are transferable across different levels of basis set truncation, enabling a cost-efficient protocol for computing vibrational spectra of high-dimensional systems.
Score: 0.0
License:
Abstract: Calculations of highly excited and delocalized molecular vibrational states is a computationally challenging task, which strongly depends on the choice of coordinates for describing vibrational motions. We introduce a new method that utilizes normalizing flows (parametrized invertible functions) to optimize vibrational coordinates to satisfy the variational principle. This approach produces coordinates specifically tailored to the vibrational problem at hand, significantly increasing the accuracy and enhancing basis set convergence of calculated energy spectrum. The efficiency of the method is demonstrated in calculations of the 100 lowest excited vibrational states of H$_2$S, H$_2$CO, and HCN/CNH. The method effectively captures the essential vibrational behavior of molecules by enhancing the separability of the Hamiltonian. We further demonstrate that the optimized coordinates are transferable across different levels of basis set truncation, enabling a cost-efficient protocol for computing vibrational spectra of high-dimensional systems.

Related papers

Single vibronic level fluorescence spectra from Hagedorn wavepacket dynamics [0.0]
We develop an efficient algorithm to compute the overlaps between two Hagedorn wavepackets. We study the effects of displacement, distortion (squeezing), and Duschinsky rotation on SVL spectra.
arXiv Detail & Related papers (2024-03-01T14:58:07Z)
Variational Equations-of-States for Interacting Quantum Hamiltonians [0.0]
We present variational equations of state (VES) for pure states of an interacting quantum Hamiltonian. VES can be expressed in terms of the variation of the density operators or static correlation functions. We present three nontrivial applications of the VES.
arXiv Detail & Related papers (2023-07-03T07:51:15Z)
Vibrational response functions for multidimensional electronic spectroscopy: from Duschinsky rotations to multimode squeezed coherent states [0.0]
We present an approach for the calculation of the response functions, based on the explicit derivation of the vibrational state. The proposed approach potentially simplifies the numerical derivation of the response functions. It substantiates in the considered models the intuitive interpretation of the response functions in terms of the vibrational wave packet dynamics.
arXiv Detail & Related papers (2023-06-15T06:41:09Z)
Optimal control for state preparation in two-qubit open quantum systems driven by coherent and incoherent controls via GRAPE approach [77.34726150561087]
We consider a model of two qubits driven by coherent and incoherent time-dependent controls. The dynamics of the system is governed by a Gorini-Kossakowski-Sudarshan-Lindblad master equation. We study evolution of the von Neumann entropy, purity, and one-qubit reduced density matrices under optimized controls.
arXiv Detail & Related papers (2022-11-04T15:20:18Z)
Say NO to Optimization: A Non-Orthogonal Quantum Eigensolver [0.0]
A balanced description of both static and dynamic correlations in electronic systems with nearly degenerate low-lying states presents a challenge for multi-configurational methods on classical computers. We present here a quantum algorithm utilizing the action of correlating cluster operators to provide high-quality wavefunction ans"atze.
arXiv Detail & Related papers (2022-05-18T16:20:36Z)
Simulation of absorption spectra of molecular aggregates: a Hierarchy of Stochastic Pure States approach [68.8204255655161]
hierarchy of pure states (HOPS) provides a formally exact solution based on local, trajectories. Exploiting the localization of HOPS for the simulation of absorption spectra in large aggregares requires a formulation in terms of normalized trajectories.
arXiv Detail & Related papers (2021-11-01T16:59:54Z)
Hybridized Methods for Quantum Simulation in the Interaction Picture [69.02115180674885]
We provide a framework that allows different simulation methods to be hybridized and thereby improve performance for interaction picture simulations. Physical applications of these hybridized methods yield a gate complexity scaling as $log2 Lambda$ in the electric cutoff. For the general problem of Hamiltonian simulation subject to dynamical constraints, these methods yield a query complexity independent of the penalty parameter $lambda$ used to impose an energy cost.
arXiv Detail & Related papers (2021-09-07T20:01:22Z)
Machine Learning for Vibrational Spectroscopy via Divide-and-Conquer Semiclassical Initial Value Representation Molecular Dynamics with Application to N-Methylacetamide [56.515978031364064]
A machine learning algorithm for partitioning the nuclear vibrational space into subspaces is introduced. The subdivision criterion is based on Liouville's theorem, i.e. best preservation of the unitary of the reduced dimensionality Jacobian determinant. The algorithm is applied to the divide-and-conquer semiclassical calculation of the power spectrum of 12-atom trans-N-Methylacetamide.
arXiv Detail & Related papers (2021-01-11T14:47:33Z)
Fingerprint region of the formic acid dimer: variational vibrational computations in curvilinear coordinates [0.0]
Curvilinear kinetic energy models are developed for variational nuclear motion computations. The coupling of the inter- and intra-molecular modes is studied by solving the vibrational Schr"odinger equation for a series of vibrational models.
arXiv Detail & Related papers (2020-12-05T11:44:42Z)
Benchmarking adaptive variational quantum eigensolvers [63.277656713454284]
We benchmark the accuracy of VQE and ADAPT-VQE to calculate the electronic ground states and potential energy curves. We find both methods provide good estimates of the energy and ground state. gradient-based optimization is more economical and delivers superior performance than analogous simulations carried out with gradient-frees.
arXiv Detail & Related papers (2020-11-02T19:52:04Z)
Fast Gravitational Approach for Rigid Point Set Registration with Ordinary Differential Equations [79.71184760864507]
This article introduces a new physics-based method for rigid point set alignment called Fast Gravitational Approach (FGA) In FGA, the source and target point sets are interpreted as rigid particle swarms with masses interacting in a globally multiply-linked manner while moving in a simulated gravitational force field. We show that the new method class has characteristics not found in previous alignment methods.
arXiv Detail & Related papers (2020-09-28T15:05:39Z)

This list is automatically generated from the titles and abstracts of the papers in this site.