Real-time time-dependent density functional theory implementation of electronic circular dichroism applied to nanoscale metal–organic clusters
Makkonen, E., Rossi, T. P., Larsen, A. H., Lopez-Acevedo, O., Rinke, P., Kuisma, M., & Chen, X. (2021). Real-time time-dependent density functional theory implementation of electronic circular dichroism applied to nanoscale metal–organic clusters. Journal of Chemical Physics, 154(11), Article 114102. https://doi.org/10.1063/5.0038904
Published in
Journal of Chemical PhysicsAuthors
Date
2021Copyright
© 2021 Author(s).
Electronic circular dichroism (ECD) is a powerful spectroscopy method for investigating chiral properties at the molecular level. ECD calculations with the commonly used linear-response time-dependent density functional theory (LR-TDDFT) framework can be prohibitively costly for large systems. To alleviate this problem, we present here an ECD implementation within the projector augmented-wave method in a real-time-propagation TDDFT framework in the open-source GPAW code. Our implementation supports both local atomic basis sets and real-space finite-difference representations of wave functions. We benchmark our implementation against an existing LR-TDDFT implementation in GPAW for small chiral molecules. We then demonstrate the efficiency of our local atomic basis set implementation for a large hybrid nanocluster and discuss the chiroptical properties of the cluster.
Publisher
AIP PublishingISSN Search the Publication Forum
0021-9606Keywords
Publication in research information system
https://converis.jyu.fi/converis/portal/detail/Publication/51983129
Metadata
Show full item recordCollections
Related funder(s)
Research Council of FinlandFunding program(s)
Postdoctoral Researcher, AoFAdditional information about funding
This work was supported by the Academy of Finland under Grant Nos. 279240, 295602, 308647, 312556, 314298, and 332429. T.P.R. also acknowledges support from the European Union’s Horizon 2020 research and innovation programme under Marie Skłodowska-Curie Grant Agreement No. 838996. We acknowledge computational resources provided by the CSC–IT Center for Science (Finland), the Aalto Science-IT project, and the Swedish National Infrastructure for Computing (SNIC) at PDC (Stockholm). ...License
Related items
Showing items with similar title or keywords.
-
GPAW : An open Python package for electronic structure calculations
Mortensen, Jens Jørgen; Larsen, Ask Hjorth; Kuisma, Mikael; Ivanov, Aleksei V.; Taghizadeh, Alireza; Peterson, Andrew; Haldar, Anubhab; Dohn, Asmus Ougaard; Schäfer, Christian; Jónsson, Elvar Örn; Hermes, Eric D.; Nilsson, Fredrik Andreas; Kastlunger, Georg; Levi, Gianluca; Jónsson, Hannes; Häkkinen, Hannu; Fojt, Jakub; Kangsabanik, Jiban; Sødequist, Joachim; Lehtomäki, Jouko; Heske, Julian; Enkovaara, Jussi; Winther, Kirsten Trøstrup; Dulak, Marcin; Melander, Marko M.; Ovesen, Martin; Louhivuori, Martti; Walter, Michael; Gjerding, Morten; Lopez-Acevedo, Olga; Erhart, Paul; Warmbier, Robert; Würdemann, Rolf; Kaappa, Sami; Latini, Simone; Boland, Tara Maria; Bligaard, Thomas; Skovhus, Thorbjørn; Susi, Toma; Maxson, Tristan; Rossi, Tuomas; Chen, Xi; Schmerwitz, Yorick Leonard A.; Schiøtz, Jakob; Olsen, Thomas; Jacobsen, Karsten Wedel; Thygesen, Kristian Sommer (American Institute of Physics, 2024)We review the GPAW open-source Python package for electronic structure calculations. GPAW is based on the projector-augmented wave method and can solve the self-consistent density functional theory (DFT) equations using ... -
A Homoleptic Alkynyl‐Ligated [Au13Ag16L24]3‐ Cluster as a Catalytically Active Eight‐Electron Superatom
Li, Gao; Hakkinen, Hannu; Qin, Zhaoxian; Sharma, Sachil; Wan, Chong-qing; Xu, Wen-wu; Malola, Sami (Wiley, 2021)A brand new alkynylated cluster [Au 13 Ag 16 (C 10 H 6 NO) 24 ] 3- is prepared by NaBH 4 mediated reduction method. The AuAg clusters are confirmed by various sophisticated characterization techniques. It manifested the ... -
Kohn-Sham Decomposition in Real-Time Time-Dependent Density-Functional Theory : An Efficient Tool for Analyzing Plasmonic Excitations
Rossi, Tuomas P.; Kuisma, Mikael; Puska, Martti J.; Nieminen, Risto M.; Erhart, Paul (American Chemical Society, 2017)Electronic excitations can be efficiently analyzed in terms of the underlying Kohn-Sham (KS) electron-hole transitions. While such a decomposition is readily available in the linear-response time-dependent density-functional ... -
Charge Transfer Plasmons in Dimeric Electron Clusters
Selenius, Elli; Malola, Sami; Kuisma, Mikael; Häkkinen, Hannu (American Chemical Society, 2020)The tunability of the optical response of dimers of metal clusters and nanoparticles makes them ideal for many applications from sensing and imaging to inducing chemical reactions. We have studied charge transfer plasmons ... -
Dipolar coupling of nanoparticle-molecule assemblies : an efficient approach for studying strong coupling
Fojt, Jakub; Rossi, Tuomas P.; Antosiewicz, Tomasz J.; Kuisma, Mikael; Erhart, Paul (American Institute of Physics, 2021)Strong light–matter interactions facilitate not only emerging applications in quantum and non-linear optics but also modifications of properties of materials. In particular, the latter possibility has spurred the development ...