Your search keyword '"Visscher, Lucas"' showing total 14 results

1. Assessing MP2 frozen natural orbitals in relativistic correlated electronic structure calculations.

Author

Yuan, Xiang, Visscher, Lucas, and Gomes, André Severo Pereira

Subjects

*NATURAL orbitals, *ELECTRONIC structure, *ELECTRIC dipole moments, *ATOMIC orbitals, *DENSITY matrices

Abstract

The high computational scaling with the basis set size and the number of correlated electrons is a bottleneck limiting applications of coupled cluster algorithms, in particular for calculations based on two- or four-component relativistic Hamiltonians, which often employ uncontracted basis sets. This problem may be alleviated by replacing canonical Hartree–Fock virtual orbitals by natural orbitals (NOs). In this paper, we describe the implementation of a module for generating NOs for correlated wavefunctions and, in particular, second order Møller–Plesset perturbation frozen natural orbitals (MP2FNOs) as a component of our novel implementation of relativistic coupled cluster theory for massively parallel architectures [Pototschnig et al. J. Chem. Theory Comput. 17, 5509, (2021)]. Our implementation can manipulate complex or quaternion density matrices, thus allowing for the generation of both Kramers-restricted and Kramers-unrestricted MP2FNOs. Furthermore, NOs are re-expressed in the parent atomic orbital (AO) basis, allowing for generating coupled cluster singles and doubles NOs in the AO basis for further analysis. By investigating the truncation errors of MP2FNOs for both the correlation energy and molecular properties—electric field gradients at the nuclei, electric dipole and quadrupole moments for hydrogen halides HX (X = F–Ts), and parity-violating energy differences for H2Z2 (Z = O–Se)—we find MP2FNOs accelerate the convergence of the correlation energy in a roughly uniform manner across the Periodic Table. It is possible to obtain reliable estimates for both energies and the molecular properties considered with virtual molecular orbital spaces truncated to about half the size of the full spaces. [ABSTRACT FROM AUTHOR]

Published

2022

2. Efficient implementation of the superposition of atomic potentials initial guess for electronic structure calculations in Gaussian basis sets.

Author

Lehtola, Susi, Visscher, Lucas, and Engel, Eberhard

Subjects

*ELECTRONIC structure, *PSEUDOPOTENTIAL method, *ERROR functions, *APPROXIMATION theory, *QUANTUM chemistry

Abstract

The superposition of atomic potentials (SAP) approach has recently been shown to be a simple and efficient way to initialize electronic structure calculations [S. Lehtola, J. Chem. Theory Comput. 15, 1593–1604 (2019)]. Here, we study the differences between effective potentials from fully numerical density functional and optimized effective potential calculations for fixed configurations. We find that the differences are small, overall, and choose exchange-only potentials at the local density approximation level of theory computed on top of Hartree–Fock densities as a good compromise. The differences between potentials arising from different atomic configurations are also found to be small at this level of theory. Furthermore, we discuss the efficient Gaussian-basis implementation of SAP via error function fits to fully numerical atomic radial potentials. The guess obtained from the fitted potentials can be easily implemented in any Gaussian-basis quantum chemistry code in terms of two-electron integrals. Fits covering the whole periodic table from H to Og are reported for non-relativistic as well as fully relativistic four-component calculations that have been carried out with fully numerical approaches. [ABSTRACT FROM AUTHOR]

Published

2020

3. Analytic one-electron properties at the 4-component relativistic coupled cluster level with inclusion of spin-orbit coupling.

Author

Shee, Avijit, Visscher, Lucas, and Saue, Trond

Subjects

*NUCLEAR electric moments, *SPIN-orbit interactions, *RELATIVISTIC electrons, *LAGRANGIAN mechanics, *DIRECT products (Mathematics), *MATHEMATICAL decomposition

Abstract

We present a formulation and implementation of the calculation of (orbital-unrelaxed) expectation values at the 4-component relativistic coupled cluster level with spin-orbit coupling included from the start. The Lagrangian-based analytical energy derivative technique constitutes the basic theoretical framework of this work. The key algorithms for single reference relativistic coupled cluster have been implemented using routines for general tensor contractions of up to rank-2 tensors in which the direct product decomposition scheme is employed to benefit from double group symmetry. As a sample application, we study the electric field gradient at the bismuth nucleus in the BiX (X = N, P) series of molecules, where the effect of spin-orbit coupling is substantial. Our results clearly indicate that the current reference value for the nuclear quadrupole moment of 209Bi needs revision. We also have applied our method to the calculation of the parity violating energy shift of chiral molecules. The latter property is strictly zero in the absence of spin-orbit coupling. For the H2X2 (X = O,S,Se,Te) series of molecules the effect of correlation is found to be quite small. [ABSTRACT FROM AUTHOR]

Published

2016

4. Characterization of excited states in time-dependent density functional theory using localized molecular orbitals.

Author

Sen, Souloke, Senjean, Bruno, and Visscher, Lucas

Subjects

*TIME-dependent density functional theory, *MOLECULAR orbitals, *EXCITED states, *DENSITY of states, *ANALYTICAL chemistry

Abstract

Localized molecular orbitals are often used for the analysis of chemical bonds, but they can also serve to efficiently and comprehensibly compute linear response properties. While conventional canonical molecular orbitals provide an adequate basis for the treatment of excited states, a chemically meaningful identification of the different excited-state processes is difficult within such a delocalized orbital basis. In this work, starting from an initial set of supermolecular canonical molecular orbitals, we provide a simple one-step top-down embedding procedure for generating a set of orbitals, which are localized in terms of the supermolecule but delocalized over each subsystem composing the supermolecule. Using an orbital partitioning scheme based on such sets of localized orbitals, we further present a procedure for the construction of local excitations and charge-transfer states within the linear response framework of time-dependent density functional theory (TDDFT). This procedure provides direct access to approximate diabatic excitation energies and, under the Tamm–Dancoff approximation, also their corresponding electronic couplings—quantities that are of primary importance in modeling energy transfer processes in complex biological systems. Our approach is compared with a recently developed diabatization procedure based on subsystem TDDFT using projection operators, which leads to a similar set of working equations. Although both of these methods differ in the general localization strategies adopted and the type of basis functions (Slaters vs Gaussians) employed, an overall decent agreement is obtained. [ABSTRACT FROM AUTHOR]

Published

2023

5. Efficient simulation of resonance Raman spectra with tight-binding approximations to density functional theory.

Author

Ashtari-Jafari, Sahar, Jamshidi, Zahra, and Visscher, Lucas

Subjects

*RESONANCE Raman effect, *DENSITY functional theory, *RESONANCE Raman spectroscopy, *VIBRATIONAL spectra

Abstract

Resonance Raman spectroscopy has long been established as one of the most sensitive techniques for detection, structure characterization, and probing the excited-state dynamics of biochemical systems. However, the analysis of resonance Raman spectra is much facilitated when measurements are accompanied by Density Functional Theory (DFT) calculations that are expensive for large biomolecules. In this work, resonance Raman spectra are therefore computed with the Density Functional Tight-Binding (DFTB) method in the time-dependent excited-state gradient approximation. To test the accuracy of the tight-binding approximations, this method is first applied to typical resonance Raman benchmark molecules, such as β-carotene, and compared to results obtained with pure and range-separated exchange–correlation functionals. We then demonstrate the efficiency of the approach by considering a computationally challenging heme variation. Overall, we find that the vibrational frequencies and excited-state properties (energies and gradients) that are needed to simulate the spectra are reasonably accurate and suitable for interpretation of experiments. We can therefore recommend DFTB as a fast computational method to interpret resonance Raman spectra. [ABSTRACT FROM AUTHOR]

Published

2022

6. High accuracy theoretical investigations of CaF, SrF, and BaF and implications for laser-cooling.

Author

Hao, Yongliang, Pašteka, Lukáš F., Visscher, Lucas, Aggarwal, Parul, Bethlem, Hendrick L., Boeschoten, Alexander, Borschevsky, Anastasia, Denis, Malika, Esajas, Kevin, Hoekstra, Steven, Jungmann, Klaus, Marshall, Virginia R., Meijknecht, Thomas B., Mooij, Maarten C., Timmermans, Rob G. E., Touwen, Anno, Ubachs, Wim, Willmann, Lorenz, Yin, Yanning, and Zapara, Artem

Subjects

*ELECTRIC dipole moments, *EXCITED states, *FRANCK-Condon principle, *MOLECULAR spectroscopy, *DIPOLE moments, *BARIUM fluoride

Abstract

The NL-eEDM collaboration is building an experimental setup to search for the permanent electric dipole moment of the electron in a slow beam of cold barium fluoride molecules [NL-eEDM Collaboration, Eur. Phys. J. D 72, 197 (2018)]. Knowledge of the molecular properties of BaF is thus needed to plan the measurements and, in particular, to determine the optimal laser-cooling scheme. Accurate and reliable theoretical predictions of these properties require the incorporation of both high-order correlation and relativistic effects in the calculations. In this work, theoretical investigations of the ground and lowest excited states of BaF and its lighter homologs, CaF and SrF, are carried out in the framework of the relativistic Fock-space coupled cluster and multireference configuration interaction methods. Using the calculated molecular properties, we determine the Franck-Condon factors (FCFs) for the A 2 Π 1 / 2 → X 2 Σ 1 / 2 + transition, which was successfully used for cooling CaF and SrF and is now considered for BaF. For all three species, the FCFs are found to be highly diagonal. Calculations are also performed for the B 2 Σ 1 / 2 + → X 2 Σ 1 / 2 + transition recently exploited for laser-cooling of CaF; it is shown that this transition is not suitable for laser-cooling of BaF, due to the nondiagonal nature of the FCFs in this system. Special attention is given to the properties of the A′2Δ state, which in the case of BaF causes a leak channel, in contrast to CaF and SrF species where this state is energetically above the excited states used in laser-cooling. We also present the dipole moments of the ground and excited states of the three molecules and the transition dipole moments (TDMs) between the different states. Finally, using the calculated FCFs and TDMs, we determine that the A 2 Π 1 / 2 → X 2 Σ 1 / 2 + transition is suitable for transverse cooling in BaF. [ABSTRACT FROM AUTHOR]

Published

2019

7. Equation-of-motion coupled-cluster theory based on the 4-component Dirac–Coulomb(–Gaunt) Hamiltonian. Energies for single electron detachment, attachment, and electronically excited states.

Author

Shee, Avijit, Saue, Trond, Visscher, Lucas, and Severo Pereira Gomes, André

Subjects

*EQUATIONS of motion, *COUPLED-cluster theory, *IONIZATION energy, *ELECTRON affinity, *SPIN-orbit interactions

Abstract

We report in this paper an implementation of a 4-component relativistic Hamiltonian based Equation-of-Motion Coupled-Cluster with singles and doubles (EOM-CCSD) theory for the calculation of ionization potential, electron affinity, and excitation energy. In this work, we utilize the previously developed double group symmetry-based generalized tensor contraction scheme and also extend it in order to carry out tensor contractions involving non-totally symmetric and odd-ranked tensors. Several approximated spin-free and two-component Hamiltonians can also be accessed in this implementation. We have applied this method to the halogen monoxide (XO, X = Cl, Br, I, At, Ts) species, in order to assess the quality of a few other recent EOM-CCSD implementations, where spin-orbit coupling contribution has been approximated in different degrees. Besides, we have also studied various excited states of CH2IBr, CH2I2, and I 3 − (as well as single electron attachment and detachment electronic states of the same species) where comparison has been made with a closely related multi-reference coupled-cluster method, namely, Intermediate Hamiltonian Fock Space Coupled-Cluster singles and doubles theory. [ABSTRACT FROM AUTHOR]

Published

2018

8. Laplace-transformed atomic orbital-based Møller-Plesset perturbation theory for relativistic two-component Hamiltonians.

Author

Helmich-Paris, Benjamin, Repisky, Michal, and Visscher, Lucas

Subjects

*ATOMIC orbital energy, *MATHEMATICAL models, *VALENCE (Chemistry), *QUANTUM chemistry, *MOLECULAR orbitals

Abstract

We present a formulation of Laplace-transformed atomic orbital-based second-order Møller-Plesset perturbation theory (MP2) energies for two-component Hamiltonians in the Kramers-restricted formalism. This low-order scaling technique can be used to enable correlated relativistic calculations for large molecular systems. We show that the working equations to compute the relativistic MP2 energy differ by merely a change of algebra (quaternion instead of real) from their non-relativistic counterparts. With a proof-of-principle implementation we study the effect of the nuclear charge on the magnitude of half-transformed integrals and show that for light elements spin-free and spin-orbit MP2 energies are almost identical. Furthermore, we investigate the effect of separation of charge distributions on the Coulomb and exchange energy contributions, which show the same long-range decay with the inter-electronic/atomic distance as for nonrelativistic MP2. A linearly scaling implementation is possible if the proper distance behavior is introduced to the quaternion Schwarz-type estimates as for non-relativistic MP2. [ABSTRACT FROM AUTHOR]

Published

2016

9. Comparing the nature of quantum plasmonic excitations for closely spaced silver and gold dimers.

Author

Jamshidi, Zahra, Asadi-Aghbolaghi, Narges, Morad, Razieh, Mahmoudi, Erfan, Sen, Souloke, Maaza, Malik, and Visscher, Lucas

Subjects

*TIME-dependent density functional theory, *GOLD nanoparticles, *PLASMONICS, *ELECTRON-electron interactions, *MOLECULAR orbitals, *DIMERS

Abstract

In the new field of quantum plasmonics, plasmonic excitations of silver and gold nanoparticles are utilized to manipulate and control light–matter interactions at the nanoscale. While quantum plasmons can be described with atomistic detail using Time-Dependent Density Functional Theory (DFT), such studies are computationally challenging due to the size of the nanoparticles. An efficient alternative is to employ DFT without approximations only for the relatively fast ground state calculations and use tight-binding approximations in the demanding linear response calculations. In this work, we use this approach to investigate the nature of plasmonic excitations under the variation of the separation distance between two nanoparticles. We thereby provide complementary characterizations of these excitations in terms of Kohn–Sham single–orbital transitions, intrinsic localized molecular fragment orbitals, scaling of the electron–electron interactions, and probability of electron tunneling between monomers. [ABSTRACT FROM AUTHOR]

Published

2022

10. The DIRAC code for relativistic molecular calculations.

Author

Saue, Trond, Bast, Radovan, Gomes, André Severo Pereira, Jensen, Hans Jørgen Aa., Visscher, Lucas, Aucar, Ignacio Agustín, Di Remigio, Roberto, Dyall, Kenneth G., Eliav, Ephraim, Fasshauer, Elke, Fleig, Timo, Halbert, Loïc, Hedegård, Erik Donovan, Helmich-Paris, Benjamin, Iliaš, Miroslav, Jacob, Christoph R., Knecht, Stefan, Laerdahl, Jon K., Vidal, Marta L., and Nayak, Malaya K.

Subjects

*COUPLED-cluster theory, *TIME reversal, *DENSITY matrices, *ALGEBRA, *QUATERNIONS, *SOLVATION, *SYMMETRY

Abstract

DIRAC is a freely distributed general-purpose program system for one-, two-, and four-component relativistic molecular calculations at the level of Hartree–Fock, Kohn–Sham (including range-separated theory), multiconfigurational self-consistent-field, multireference configuration interaction, electron propagator, and various flavors of coupled cluster theory. At the self-consistent-field level, a highly original scheme, based on quaternion algebra, is implemented for the treatment of both spatial and time reversal symmetry. DIRAC features a very general module for the calculation of molecular properties that to a large extent may be defined by the user and further analyzed through a powerful visualization module. It allows for the inclusion of environmental effects through three different classes of increasingly sophisticated embedding approaches: the implicit solvation polarizable continuum model, the explicit polarizable embedding model, and the frozen density embedding model. [ABSTRACT FROM AUTHOR]

Published

2020

11. Vibrationally resolved UV/Vis spectroscopy with time-dependent density functional based tight binding.

Author

Rüger, Robert, Niehaus, Thomas, van Lenthe, Erik, Heine, Thomas, and Visscher, Lucas

Subjects

*FRANCK-Condon principle, *NUCLEAR vibrational states, *DENSITY functional theory, *ELECTRONIC excitation, *WAVE functions, *ULTRAVIOLET-visible spectroscopy

Abstract

We report a time-dependent density functional based tight-binding (TD-DFTB) scheme for the calculation of UV/Vis spectra, explicitly taking into account the excitation of nuclear vibrations via the adiabatic Hessian Franck-Condon method with a harmonic approximation for the nuclear wavefunction. The theory of vibrationally resolved UV/Vis spectroscopy is first summarized from the viewpoint of TD-DFTB. The method is benchmarked against time-dependent density functional theory (TD-DFT) calculations for strongly dipole allowed excitations in various aromatic and polar molecules. Using the recent 3ob:freq parameter set of Elstner's group, very good agreement with TD-DFT calculations using local functionals was achieved. [ABSTRACT FROM AUTHOR]

Published

2016

12. Tight-binding approximations to time-dependent density functional theory -- A fast approach for the calculation of electronically excited states.

Author

Rüger, Robert, van Lenthe, Erik, Heine, Thomas, and Visscher, Lucas

Subjects

*DENSITY functional theory, *ABSORPTION spectra, *ULTRAVIOLET spectra, *APPROXIMATION theory, *EXCITED states, *ELECTRONIC structure

Abstract

We propose a new method of calculating electronically excited states that combines a density functional theory based ground state calculation with a linear response treatment that employs approximations used in the time-dependent density functional based tight binding (TD-DFTB) approach. The new method termed time-dependent density functional theory TD-DFT+TB does not rely on the DFTB parametrization and is therefore applicable to systems involving all combinations of elements. We show that the new method yields UV/Vis absorption spectra that are in excellent agreement with computationally much more expensive TD-DFT calculations. Errors in vertical excitation energies are reduced by a factor of two compared to TD-DFTB. [ABSTRACT FROM AUTHOR]

Published

2016

13. The ground-state potential energy curve of the radium dimer from relativistic coupled cluster calculations.

Author

Teodoro, Tiago Quevedo, Andrade Haiduke, Roberto Luiz, Dammalapati, Umakanth, Knoop, Steven, and Visscher, Lucas

Subjects

*GROUND state (Quantum mechanics), *POTENTIAL energy surfaces, *RADIUM isotopes, *DIMERS, *RELATIVITY (Physics), *MICROCLUSTERS

Abstract

The potential energy curve for the ground-state of radium dimer (Ra2) is provided by means of atomic and molecular relativistic coupled cluster calculations. The short-range part of this curve is defined by an equilibrium bond length of 5.324 Å, a dissociation energy of 897 cm-1, and a harmonic vibrational frequency of 20.5 cm-1. The asymptotic behavior at large interatomic distances is characterized by the van der Waals coefficients C6 = 5.090 × 10³, C8 = 6.978 × 105, and C10 = 8.786 × 107 atomic units. The two regions are matched in an analytical potential to provide a convenient representation for use in further calculations, for instance, to model cold collisions between radium atoms. This might become relevant in future experiments on ultracold, optically trapped, radioactive radium atoms that are used to search for a permanent electric dipole moment. [ABSTRACT FROM AUTHOR]

Published

2015

14. Communication: Relativistic Fock-space coupled cluster study of small building blocks of larger uranium complexes.

Author

Tecmer, Paweł, Pereira Gomes, André Severo, Knecht, Stefan, and Visscher, Lucas

Subjects

*RELATIVITY (Physics), *URANIUM compounds, *FOCK spaces, *METAL complexes, *ELECTRONIC structure, *SPIN-orbit interactions, *MICROCLUSTERS

Abstract

We present a study of the electronic structure of the [UO2]+, [UO2]2 +, [UO2]3+, NUO, [NUO]+, [NUO]2+, [NUN]-, NUN, and [NUN]+ molecules with the intermediate Hamiltonian Fock-space coupled cluster method. The accuracy of mean-field approaches based on the eXact-2-Component Hamiltonian to incorporate spin-orbit coupling and Gaunt interactions are compared to results obtained with the Dirac-Coulomb Hamiltonian. Furthermore, we assess the reliability of calculations employing approximate density functionals in describing electronic spectra and quantities useful in rationalizing Uranium (VI) species reactivity (hardness, electronegativity, and electrophilicity). [ABSTRACT FROM AUTHOR]

Published

2014