Your search keyword '"Rostgaard, C."' showing total 14 results

1. First-principles many-body calculations of electronic conduction in thiol- and amine-linked molecules

Author

Strange, M., Rostgaard, C., Hakkinen, H., and Thygesen, K. S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The electronic conductance of a benzene molecule connected to gold electrodes via thiol, thiolate, and amino anchoring groups is calculated using nonequilibrium Green functions in combination with the fully selfconsistent GW approximation. The calculated conductance of benzenedithiol and benzenediamine is five times lower than predicted by standard density functional theory (DFT) in very good agreement with experiments. In contrast, the widely studied benzenedithiolate structure is found to have a significantly higher conductance due to the unsaturated sulfur bonds. These findings suggest that more complex gold/thiolate structures where the thiolate anchors are chemically passivated by Au adatoms are responsible for the measured conductance. Analysis of the energy level alignment obtained with DFT, Hartree-Fock and GW reveals the importance of self-interaction corrections (exchange) on the molecule and dynamical screening at the metal-molecule interface. The main effect of the GW self-energy is to renormalize the level positions, however, its influence on the shape of molecular resonances also affects the conductance. Non-selfconsistent G0W0 calculations, starting from either DFT or Hartree-Fock, yield conductance values within 50% of the selfconsistent GW results., Comment: 13 pages, 8 figures, to appear in PRB

Published

2011

2. Fully selfconsistent GW calculations for molecules

Author

Rostgaard, C., Jacobsen, K. W., and Thygesen, K. S.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We calculate single-particle excitation energies for a series of 33 molecules using fully selfconsistent GW, one-shot G$_0$W$_0$, Hartree-Fock (HF), and hybrid density functional theory (DFT). All calculations are performed within the projector augmented wave (PAW) method using a basis set of Wannier functions augmented by numerical atomic orbitals. The GW self-energy is calculated on the real frequency axis including its full frequency dependence and off-diagonal matrix elements. The mean absolute error of the ionization potential (IP) with respect to experiment is found to be 4.4, 2.6, 0.8, 0.4, and 0.5 eV for DFT-PBE, DFT-PBE0, HF, G$_0$W$_0$[HF], and selfconsistent GW, respectively. This shows that although electronic screening is weak in molecular systems its inclusion at the GW level reduces the error in the IP by up to 50% relative to unscreened HF. In general GW overscreens the HF energies leading to underestimation of the IPs. The best IPs are obtained from one-shot G$_0$W$_0$ calculations based on HF since this reduces the overscreening. Finally, we find that the inclusion of core-valence exchange is important and can affect the excitation energies by as much as 1 eV., Comment: 10 pages, 5 figures

Published

2010

3. Polarization-induced renormalization of molecular levels at metallic and semiconducting surfaces

Author

Garcia-Lastra, J. M., Rostgaard, C., Rubio, A., and Thygesen, K. S.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

On the basis of first-principles G0W0 calculations we study systematically how the electronic levels of a benzene molecule are renormalized by substrate polarization when physisorbed on different metallic and semiconducting surfaces. The polarization-induced reduction of the energy gap between occupied and unoccupied molecular levels is found to scale with the substrate density of states at the Fermi level (for metals) and substrate band gap (for semiconductors). These conclusions are further supported by GW calculations on simple lattice models. By expressing the electron self-energy in terms of the substrate's joint density of states we relate the level shift to the surface electronic structure thus providing a microscopic explanation of the trends in the G0W0 calculations. While image charge effects are not captured by semi-local and hybrid exchange-correlation functionals, we find that error cancellations lead to remarkably good agreement between the G0W0 and Kohn-Sham energies for the occupied orbitals of the adsorbed molecule., Comment: Extended version, 8 pages, accepted in PRB

Published

2009

4. The atomic simulation environment - a Python library for working with atoms

Author

Hjorth Larsen, A., JØrgen Mortensen, J., Blomqvist, J., Castelli, I.E., Christensen, R., Dulak, M., Friis, J., Groves, M.N., Hammer, B., Hargus, C., Hermes, E.D., Jennings, P.C., Bjerre Jensen, P., Kermode, J., Kitchin, J.R., Leonhard Kolsbjerg, E., Kubal, J., Kaasbjerg, K., Lysgaard, S., Bergmann Maronsson, J., Maxson, T., Olsen, T., Pastewka, L., Peterson, A., Rostgaard, C., and Publica

Abstract

The atomic simulation environment (ASE) is a software package written in the Python programming language with the aim of setting up, steering, and analyzing atomistic simulations. In ASE, tasks are fully scripted in Python. The powerful syntax of Python combined with the NumPy array library make it possible to perform very complex simulation tasks. For example, a sequence of calculations may be performed with the use of a simple 'for-loop' construction. Calculations of energy, forces, stresses and other quantities are performed through interfaces to many external electronic structure codes or force fields using a uniform interface. On top of this calculator interface, ASE provides modules for performing many standard simulation tasks such as structure optimization, molecular dynamics, handling of constraints and performing nudged elastic band calculations.

Published

2017

5. Electronic structure calculations with GPAW : a real-space implementation of the projector augmented-wave method

Author

Enkovaara, J., Rostgaard, C., Mortensen, J. J., Chen, J., Dulak, M., Ferrighi, L., Gavnholt, J., Glinsvad, C., Haikola, V., Hansen, H. A., Kristoffersen, H. H., Kuisma, M., Larsen, A. H., Lehtovaara, L., Ljungberg, Mathias, Lopez-Acevedo, O., Moses, P. G., Ojanen, J., Olsen, T., Petzold, V., Romero, N. A., Stausholm-Moller, J., Strange, M., Tritsaris, G. A., Vanin, M., Walter, M., Hammer, B., Hakkinen, H., Madsen, G. K. H., Nieminen, R. M., Norskov, J. K., Puska, M., Rantala, T. T., Schiotz, J., Thygesen, K. S., Jacobsen, K. W., Enkovaara, J., Rostgaard, C., Mortensen, J. J., Chen, J., Dulak, M., Ferrighi, L., Gavnholt, J., Glinsvad, C., Haikola, V., Hansen, H. A., Kristoffersen, H. H., Kuisma, M., Larsen, A. H., Lehtovaara, L., Ljungberg, Mathias, Lopez-Acevedo, O., Moses, P. G., Ojanen, J., Olsen, T., Petzold, V., Romero, N. A., Stausholm-Moller, J., Strange, M., Tritsaris, G. A., Vanin, M., Walter, M., Hammer, B., Hakkinen, H., Madsen, G. K. H., Nieminen, R. M., Norskov, J. K., Puska, M., Rantala, T. T., Schiotz, J., Thygesen, K. S., and Jacobsen, K. W.

Abstract

Electronic structure calculations have become an indispensable tool in many areas of materials science and quantum chemistry. Even though the Kohn-Sham formulation of the density-functional theory (DFT) simplifies the many-body problem significantly, one is still confronted with several numerical challenges. In this article we present the projector augmented-wave (PAW) method as implemented in the GPAW program package (https://wiki.fysik.dtu.dk/gpaw) using a uniform real-space grid representation of the electronic wavefunctions. Compared to more traditional plane wave or localized basis set approaches, real-space grids offer several advantages, most notably good computational scalability and systematic convergence properties. However, as a unique feature GPAW also facilitates a localized atomic-orbital basis set in addition to the grid. The efficient atomic basis set is complementary to the more accurate grid, and the possibility to seamlessly switch between the two representations provides great flexibility. While DFT allows one to study ground state properties, time-dependent density-functional theory (TDDFT) provides access to the excited states. We have implemented the two common formulations of TDDFT, namely the linear-response and the time propagation schemes. Electron transport calculations under finite-bias conditions can be performed with GPAW using non-equilibrium Green functions and the localized basis set. In addition to the basic features of the real-space PAW method, we also describe the implementation of selected exchange-correlation functionals, parallelization schemes, Delta SCF-method, x-ray absorption spectra, and maximally localized Wannier orbitals., authorCount :36

Published

2010

6. Self-consistent GW calculations of electronic transport in thiol- and amine-linked molecular junctions

Author

Strange, M., primary, Rostgaard, C., additional, Häkkinen, H., additional, and Thygesen, K. S., additional

Published

2011

7. Electronic structure calculations with GPAW: a real-space implementation of the projector augmented-wave method

Author

Enkovaara, J, primary, Rostgaard, C, additional, Mortensen, J J, additional, Chen, J, additional, Dułak, M, additional, Ferrighi, L, additional, Gavnholt, J, additional, Glinsvad, C, additional, Haikola, V, additional, Hansen, H A, additional, Kristoffersen, H H, additional, Kuisma, M, additional, Larsen, A H, additional, Lehtovaara, L, additional, Ljungberg, M, additional, Lopez-Acevedo, O, additional, Moses, P G, additional, Ojanen, J, additional, Olsen, T, additional, Petzold, V, additional, Romero, N A, additional, Stausholm-Møller, J, additional, Strange, M, additional, Tritsaris, G A, additional, Vanin, M, additional, Walter, M, additional, Hammer, B, additional, Häkkinen, H, additional, Madsen, G K H, additional, Nieminen, R M, additional, Nørskov, J K, additional, Puska, M, additional, Rantala, T T, additional, Schiøtz, J, additional, Thygesen, K S, additional, and Jacobsen, K W, additional

Published

2010

8. Fully self-consistent GW calculations for molecules

Author

Rostgaard, C., primary, Jacobsen, K. W., additional, and Thygesen, K. S., additional

Published

2010

9. Publisher's Note: Polarization-induced renormalization of molecular levels at metallic and semiconducting surfaces [Phys. Rev. B80, 245427 (2009)]

Author

Garcia-Lastra, J. M., primary, Rostgaard, C., additional, Rubio, A., additional, and Thygesen, K. S., additional

Published

2010

10. Polarization-induced renormalization of molecular levels at metallic and semiconducting surfaces

Author

Garcia-Lastra, J. M., primary, Rostgaard, C., additional, Rubio, A., additional, and Thygesen, K. S., additional

Published

2009

11. Density functional theory based screening of ternary alkali-transition metal borohydrides: A computational material design project

Author

Hummelshøj, J. S., primary, Landis, D. D., additional, Voss, J., additional, Jiang, T., additional, Tekin, A., additional, Bork, N., additional, Dułak, M., additional, Mortensen, J. J., additional, Adamska, L., additional, Andersin, J., additional, Baran, J. D., additional, Barmparis, G. D., additional, Bell, F., additional, Bezanilla, A. L., additional, Bjork, J., additional, Björketun, M. E., additional, Bleken, F., additional, Buchter, F., additional, Bürkle, M., additional, Burton, P. D., additional, Buus, B. B., additional, Calborean, A., additional, Calle-Vallejo, F., additional, Casolo, S., additional, Chandler, B. D., additional, Chi, D. H., additional, Czekaj, I, additional, Datta, S., additional, Datye, A., additional, DeLaRiva, A., additional, Despoja, V, additional, Dobrin, S., additional, Engelund, M., additional, Ferrighi, L., additional, Frondelius, P., additional, Fu, Q., additional, Fuentes, A., additional, Fürst, J., additional, García-Fuente, A., additional, Gavnholt, J., additional, Goeke, R., additional, Gudmundsdottir, S., additional, Hammond, K. D., additional, Hansen, H. A., additional, Hibbitts, D., additional, Hobi, E., additional, Howalt, J. G., additional, Hruby, S. L., additional, Huth, A., additional, Isaeva, L., additional, Jelic, J., additional, Jensen, I. J. T., additional, Kacprzak, K. A., additional, Kelkkanen, A., additional, Kelsey, D., additional, Kesanakurthi, D. S., additional, Kleis, J., additional, Klüpfel, P. J., additional, Konstantinov, I, additional, Korytar, R., additional, Koskinen, P., additional, Krishna, C., additional, Kunkes, E., additional, Larsen, A. H., additional, Lastra, J. M. G., additional, Lin, H., additional, Lopez-Acevedo, O., additional, Mantega, M., additional, Martínez, J. I., additional, Mesa, I. N., additional, Mowbray, D. J., additional, Mýrdal, J. S. G., additional, Natanzon, Y., additional, Nistor, A., additional, Olsen, T., additional, Park, H., additional, Pedroza, L. S., additional, Petzold, V, additional, Plaisance, C., additional, Rasmussen, J. A., additional, Ren, H., additional, Rizzi, M., additional, Ronco, A. S., additional, Rostgaard, C., additional, Saadi, S., additional, Salguero, L. A., additional, Santos, E. J. G., additional, Schoenhalz, A. L., additional, Shen, J., additional, Smedemand, M., additional, Stausholm-Møller, O. J., additional, Stibius, M., additional, Strange, M., additional, Su, H. B., additional, Temel, B., additional, Toftelund, A., additional, Tripkovic, V, additional, Vanin, M., additional, Viswanathan, V, additional, Vojvodic, A., additional, Wang, S., additional, Wellendorff, J., additional, Thygesen, K. S., additional, Rossmeisl, J., additional, Bligaard, T., additional, Jacobsen, K. W., additional, Nørskov, J. K., additional, and Vegge, T., additional

Published

2009

12. The atomic simulation environment-a Python library for working with atoms.

Author

Hjorth Larsen A, Jørgen Mortensen J, Blomqvist J, Castelli IE, Christensen R, Dułak M, Friis J, Groves MN, Hammer B, Hargus C, Hermes ED, Jennings PC, Bjerre Jensen P, Kermode J, Kitchin JR, Leonhard Kolsbjerg E, Kubal J, Kaasbjerg K, Lysgaard S, Bergmann Maronsson J, Maxson T, Olsen T, Pastewka L, Peterson A, Rostgaard C, Schiøtz J, Schütt O, Strange M, Thygesen KS, Vegge T, Vilhelmsen L, Walter M, Zeng Z, and Jacobsen KW

Abstract

The atomic simulation environment (ASE) is a software package written in the Python programming language with the aim of setting up, steering, and analyzing atomistic simulations. In ASE, tasks are fully scripted in Python. The powerful syntax of Python combined with the NumPy array library make it possible to perform very complex simulation tasks. For example, a sequence of calculations may be performed with the use of a simple 'for-loop' construction. Calculations of energy, forces, stresses and other quantities are performed through interfaces to many external electronic structure codes or force fields using a uniform interface. On top of this calculator interface, ASE provides modules for performing many standard simulation tasks such as structure optimization, molecular dynamics, handling of constraints and performing nudged elastic band calculations.

Published

2017

13. Time-dependent density-functional theory in the projector augmented-wave method.

Author

Walter M, Häkkinen H, Lehtovaara L, Puska M, Enkovaara J, Rostgaard C, and Mortensen JJ

Abstract

We present the implementation of the time-dependent density-functional theory both in linear-response and in time-propagation formalisms using the projector augmented-wave method in real-space grids. The two technically very different methods are compared in the linear-response regime where we found perfect agreement in the calculated photoabsorption spectra. We discuss the strengths and weaknesses of the two methods as well as their convergence properties. We demonstrate different applications of the methods by calculating excitation energies and excited state Born-Oppenheimer potential surfaces for a set of atoms and molecules with the linear-response method and by calculating nonlinear emission spectra using the time-propagation method.

Published

2008

14. Appendectomy and ulcerative colitis.

Author

Frisch M and Rostgaard C

Subjects

Adult, Age Factors, Colitis, Ulcerative etiology, Colon surgery, Female, Follow-Up Studies, Humans, Male, Risk Factors, Appendectomy, Colitis, Ulcerative surgery

Published

2005