Your search keyword '"Groenenboom, Gerrit C."' showing total 8 results

1. Line-shape theory of the X3∑-g → a1Δg, b1∑+g transitions in O2--O2 collision-induced absorption.

Author

Karman, Tijs, van der Avoird, Ad, and Groenenboom, Gerrit C.

Subjects

SELECTION rules (Nuclear physics), NUCLEAR spin, DIPOLE moments, PARAMAGNETIC materials, SPIN-orbit interactions, INTERMOLECULAR interactions

Abstract

We derive the theory of collision-induced absorption for electronic transitions in the approximation of an isotropic interaction potential. We apply this theory to the spin-forbidden X3∑-g →a1Δg and X3∑-g → b1∑+g transitions in O2-O2, which are relevant for calibration in atmospheric studies. We consider two mechanisms for breaking the spin symmetry, either by the intermolecular exchange interaction between paramagnetic collision partners or by the intramolecular spin-orbit coupling. The calculations for the exchange-based mechanism employ the diabatic potential energy surfaces and transition dipole moment surfaces reported in Paper I [T. Karman et al., J. Chem. Phys. 147, 084306 (2017)]. We show that the line shape of the theoretical absorption spectra is insensitive to the large uncertainty in the electronic transition dipole moment surfaces. We also perform calculations using a simple model of the alternative mechanism involving intramolecular spin-orbit coupling, which leads to absorption intensities which are well below the experimental results. The relative intensity of this spin-orbit-based mechanism may impact the relative contribution to the absorption by collisions with diamagnetic collision partners, such as the atmospherically relevant N2 molecule. We furthermore show that both the line shape and temperature dependence are signatures of the underlying transition mechanism. [ABSTRACT FROM AUTHOR]

Published

2017

2. Potential energy and dipole moment surfaces of the triplet states of the O2(X3∑-g) - O2(X3∑-g, a1Δg, b1∑+g) complex

Author

Karman, Tijs, van der Avoird, Ad, and Groenenboom, Gerrit C.

Subjects

TRIPLET state (Quantum mechanics), POTENTIAL energy surfaces, DIPOLE moments, MOLECULAR dynamics, MAGNETIC dipoles

Abstract

We compute four-dimensional diabatic potential energy surfaces and transition dipole moment surfaces of O2-O2, relevant for the theoretical description of collision-induced absorption in the forbidden X3∑-g → a1Δg and X3∑-g →b1∑+g bands at 7883 cm-1 and 13 122 cm-1, respectively. We compute potentials at the multi-reference configuration interaction (MRCI) level and dipole surfaces at the MRCI and complete active space self-consistent field (CASSCF) levels of theory. Potentials and dipole surfaces are transformed to a diabatic basis using a recent multiple-property-based diabatization algorithm. We discuss the angular expansion of these surfaces, derive the symmetry constraints on the expansion coefficients, and present working equations for determining the expansion coefficients by numerical integration over the angles. We also present an interpolation scheme with exponential extrapolation to both short and large separations, which is used for representing the O2-O2 distance dependence of the angular expansion coefficients. For the triplet ground state of the complex, the potential energy surface is in reasonable agreement with previous calculations, whereas global excited state potentials are reported here for the first time. The transition dipole moment surfaces are strongly dependent on the level of theory at which they are calculated, as is also shown here by benchmark calculations at high symmetry geometries. Therefore, ab initio calculations of the collision-induced absorption spectra cannot become quantitatively predictive unless more accurate transition dipole surfaces can be computed. This is left as an open question for method development in electronic structure theory. The calculated potential energy and transition dipole moment surfaces are employed in quantum dynamical calculations of collision-induced absorption spectra reported in Paper II [T. Karman et al., J. Chem. Phys. 147, 084307 (2017)]. [ABSTRACT FROM AUTHOR]

Published

2017

3. Quantum mechanical calculation of the collision-induced absorption spectra of N2-N2 with anisotropic interactions.

Author

Karman, Tijs, Miliordos, Evangelos, Hunt, Katharine L. C., Groenenboom, Gerrit C., and van der Avoird, Ad

Subjects

POTENTIAL energy surfaces, ABSORPTION spectra, DIPOLE moments, NITROGEN, ANISOTROPY, WAVE functions, QUANTUM mechanics, COLLISIONS (Physics)

Abstract

We present quantum mechanical calculations of the collision-induced absorption spectra of nitrogen molecules, using ab initio dipole moment and potential energy surfaces. Collision-induced spectra are first calculated using the isotropic interaction approximation. Then, we improve upon these results by considering the full anisotropic interaction potential. We also develop the computationally less expensive coupled-states approximation for calculating collision-induced spectra and validate this approximation by comparing the results to numerically exact close-coupling calculations for low energies. Angular localization of the scattering wave functions due to anisotropic interactions affects the line strength at low energies by two orders of magnitude. The effect of anisotropy decreases at higher energy, which validates the isotropic interaction approximation as a high-temperature approximation for calculating collision-induced spectra. Agreement with experimental data is reasonable in the isotropic interaction approximation, and improves when the full anisotropic potential is considered. Calculated absorption coefficients are tabulated for application in atmospheric modeling. [ABSTRACT FROM AUTHOR]

Published

2015

4. Line strengths of rovibrational and rotational transitions within the X³Σ- ground state of NH.

Author

Brooke, James S. A., Bernath, Peter F., Western, Colin M., van Hemert, Marc C., and Groenenboom, Gerrit C.

Subjects

GROUND state (Quantum mechanics), MOLECULAR structure, SPECTRUM analysis, NUMERICAL calculations, DIPOLE moments, FINE structure (Physics)

Abstract

A new line list for rovibrational and rotational transitions, including fine structure, within the NH X³Σ - ground state has been created. It contains line intensities in the form of Einstein A and fvalues, for all possible bands up to v' = 6, and for J up to between 25 and 44. The intensities are based on a new dipole moment function (DMF), which has been calculated using the internally contracted multi-reference configuration interaction method with an aug-cc-pV6Z basis set. The programs RKR1, LEVEL, and PGOPHER were used to calculate line positions and intensities using the most recent spectroscopic line position observations and the new DMF, including the rotational dependence on the matrix elements. The Hund's case (b) matrix elements from the LEVEL output (available as Supplement 1 of the supplementary material) have been transformed to the case (a) form required by PGOPHER. New relative intensities for the (1,0) band have been measured, and the calculated and observed Herman-Wallis effects are compared, showing good agreement. The line list (see Supplement 5 of the supplementary material) will be useful for the study of NH in astronomy, cold and ultracold molecular systems, and in the nitrogen chemistry of combustion. [ABSTRACT FROM AUTHOR]

Published

2014

5. New ab initio potential energy surface and the vibration-rotation-tunneling levels of (H2O)2 and (D2O)2.

Author

Huang, X., Braams, Bastiaan J., Bowman, Joel M., Kelly, Ross E. A., Tennyson, Jonathan, Groenenboom, Gerrit C., and van der Avoird, Ad

Subjects

POTENTIAL energy surfaces, SPIN excitations, DIPOLE moments, CHEMISTRY, PHYSICS

Abstract

We report a new full-dimensional potential energy surface (PES) for the water dimer, based on fitting energies at roughly 30 000 configurations obtained with the coupled-cluster single and double, and perturbative treatment of triple excitations method using an augmented, correlation consistent, polarized triple zeta basis set. A global dipole moment surface based on Mo\ller-Plesset perturbation theory results at these configurations is also reported. The PES is used in rigorous quantum calculations of intermolecular vibrational frequencies, tunneling splittings, and rotational constants for (H2O)2 and (D2O)2, using the rigid monomer approximation. Agreement with experiment is excellent and is at the highest level reported to date. The validity of this approximation is examined by comparing tunneling barriers within that model with those from fully relaxed calculations. [ABSTRACT FROM AUTHOR]

Published

2008

6. Producing translationally cold, ground-state CO molecules.

Author

Blokland, Janneke H., Riedel, Jens, Putzke, Stephan, Sartakov, Boris G., Groenenboom, Gerrit C., and Meijer, Gerard

Subjects

PHASE transitions, GROUND state (Quantum mechanics), CARBON monoxide, ELECTRONIC structure, VIBRATION (Mechanics), OPTICAL transfer function, DIPOLE moments, QUANTUM perturbations

Abstract

Carbon monoxide molecules in their electronic, vibrational, and rotational ground state are highly attractive for trapping experiments. The optical or ac electric traps that can be envisioned for these molecules will be very shallow, however, with depths in the sub-milliKelvin range. Here, we outline that the required samples of translationally cold CO (X1Σ+, v′′ = 0, N′′ = 0) molecules can be produced after Stark deceleration of a beam of laser-prepared metastable CO (a3Π1) molecules followed by optical transfer of the metastable species to the ground state via perturbed levels in the A1Π state. The optical transfer scheme is experimentally demonstrated and the radiative lifetimes and the electric dipole moments of the intermediate levels are determined. [ABSTRACT FROM AUTHOR]

Published

2011

7. New ab initio potential energy surface and the vibration-rotation-tunneling levels of (H2O)2 and (D2O)2.

Author

Huang, X., Braams, Bastiaan J., Bowman, Joel M., Kelly, Ross E. A., Tennyson, Jonathan, Groenenboom, Gerrit C., and van der Avoird, Ad

Subjects

*POTENTIAL energy surfaces, *SPIN excitations, *DIPOLE moments, *CHEMISTRY, *PHYSICS

Abstract

We report a new full-dimensional potential energy surface (PES) for the water dimer, based on fitting energies at roughly 30 000 configurations obtained with the coupled-cluster single and double, and perturbative treatment of triple excitations method using an augmented, correlation consistent, polarized triple zeta basis set. A global dipole moment surface based on Mo\ller-Plesset perturbation theory results at these configurations is also reported. The PES is used in rigorous quantum calculations of intermolecular vibrational frequencies, tunneling splittings, and rotational constants for (H2O)2 and (D2O)2, using the rigid monomer approximation. Agreement with experiment is excellent and is at the highest level reported to date. The validity of this approximation is examined by comparing tunneling barriers within that model with those from fully relaxed calculations. [ABSTRACT FROM AUTHOR]

Published

2008

8. Photoinduced Two-Body Loss of Ultracold Molecules.

Author

Christianen, Arthur, Zwierlein, Martin W., Groenenboom, Gerrit C., and Karman, Tijs

Subjects

*QUASIMOLECULES, *ELECTRONIC excitation, *DIPOLE moments, *ULTRACOLD molecules, *STATISTICAL models, *LASERS

Abstract

The lifetime of nonreactive ultracold bialkali gases was conjectured to be limited by sticky collisions amplifying three-body loss. We show that the sticking times were previously overestimated and do not support this hypothesis. We find that electronic excitation of NaK+NaK collision complexes by the trapping laser leads to the experimentally observed two-body loss. We calculate the excitation rate with a quasiclassical, statistical model employing ab initio potentials and transition dipole moments. Using longer laser wavelengths or repulsive box potentials may suppress the losses. [ABSTRACT FROM AUTHOR]

Published

2019