AI Article Synopsis
- Computational modeling of organic interface formation on semiconductors is complicated due to the intricate structures and chemistry involved, making traditional density functional theory less effective.
- A hierarchical modeling approach is proposed, where sections of the interface are simplified to improve computational efficiency without sacrificing accuracy.
- Benchmark tests indicate that while generalized gradient approximation functionals work well for reaction energies, hybrid functionals are necessary for precise reaction barriers; the model also helps in developing strategies to prevent unwanted growth terminations in organic layers on semiconductor surfaces.
Article Abstract
Computational modeling of organic interface formation on semiconductors poses a challenge to a density functional theory-based description due to structural and chemical complexity. A hierarchical approach is presented, where parts of the interface are successively removed in order to increase computational efficiency while maintaining the necessary accuracy. First, a benchmark is performed to probe the validity of this approach for three model reactions and five dispersion corrected density functionals. Reaction energies are generally well reproduced by generalized gradient approximation-type functionals but accurate reaction barriers require the use of hybrid functionals. Best performance is found for the model system that does not explicitly consider the substrate but includes its templating effects. Finally, this efficient model is used to provide coverage dependent reaction energies and suggest synthetic principles for the prevention of unwanted growth termination reactions for organic layers on semiconductor surfaces.
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| http://dx.doi.org/10.1002/jcc.26503 | DOI Listing |
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