Structure Formation of C<sub>60</sub> on Insulating CaF<sub>2</sub> Substrates: Matching Experiments with Simulations

Janke, Wolfhard; Höltkemeier, Lukas; Kühnle, Angelika; Speck, Thomas

doi:10.1002/admi.202201510

Cited by 2 publications

(1 citation statement)

References 58 publications

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“…The kinetic Monte Carlo (kMC) method is an established method in solid state physics to simulate diffusion and migration processes in the bulk or on the surface. [127][128][129][130][131][132] In this work, the same method was implemented according to the equations by Voter [133] and employed to simulate a system as it moves from a reagent to a product across a network of reactions, as the fundamental kinetic principles are the same as for a diffusion or migration process. In principle, the Gibbs free activation energy Δ𝐺 ‡ 𝑖 𝑗 at temperature 𝑇 is the only property required for the kMC simulation, yielding the corresponding rate constant 𝑘 𝑖 𝑗 for a reaction from state 𝑖 to 𝑗 as…”

Section: Kinetic Monte Carlo Simulationmentioning

confidence: 99%

FandMcenters in alkali halides: A theoretical study applying self-consistent dielectric-dependent hybrid density functional theory

Häfner

Bredow

2020

Phys. Rev. B

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I thank all my colleagues at the Mulliken center and the Bredow workgroup for the cordial and inspiring working atmosphere. Foremost, my thanks go to Manuel Hochheim for inspiring the topic of this thesis, to Sebastian Ehlert and Hagen Neugebauer for all the interesting discussions throughout my studies and my doctorate, and to my office partner Benjamin Grimm for the insightful conversations. I also want to thank Michael Chernishov, Sakyo Ochi, and Julia-Christin Denke for the interesting discussions and exchange during their bachelor and master theses. Furthermore, I thank Claudia Kronz for the administrative support during my Ph.D. studies.I thank the Studienstiftung des deutschen Volkes for their financial and non-material support for my thesis, Dieter Meschede as my tutor at the Studienstiftung, as well as Vit Kortus and all participants of the 2022 writing workshop by the Studienstiftung for the fruitful exchange and encouraging atmosphere that helped me in writing this thesis. Moreover, I thank the Choralschola of St. Cyprian, the choir of the Collegium Musicum Bonn, the Kammerchor der Universität Bonn, and especially the Vokalensemble of the Collegium Musicum Bonn for providing a musical balance for my studies in Bonn and so many unforgettable concerts and experiences.Finally, I thank my family for their tremendous support over all the years, for always encouraging me and having my back.

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Section: Kinetic Monte Carlo Simulationmentioning

confidence: 99%

FandMcenters in alkali halides: A theoretical study applying self-consistent dielectric-dependent hybrid density functional theory

Häfner

Bredow

2020

Phys. Rev. B

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Nonequilibrium Structures of C₆₀ on CaF₂(111): Exploring Structural Variability by Different Sample Preparation Pathways

Höltkemeier,

Janke,

Speck

et al. 2024

J. Phys. Chem. C

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Molecular self-assembly is considered a promising tool for creating functional molecular structures on surfaces, e.g., for future molecular electronic devices and sensor applications. In molecular self-assembly, the target structure is encoded in the molecular building blocks, which are driven toward their thermodynamically favored arrangement on the surface. This approach is, however, intrinsically limited to a single molecular pattern on the surface. Structures beyond this thermodynamic ground state minimizing the free energy might become accessible through competing pathways. Here, we make use of different sample preparation pathways for arriving at distinctly different molecular structures of C 60 on the (111) cleavage plane of the calcium fluoride. Using dynamic atomic force microscopy operated in an ultrahigh vacuum, we investigate the resulting island geometries as a function of the preparation pathway. When deposited onto the surface at low temperatures (about 120 K), C 60 forms single-layer hexagonal islands. Upon heating to about 320 K, these islands transform into double-layer islands with irregular edges (two-step experiment). Interestingly, distinctly different, truncated triangular double-layer islands are obtained from a direct preparation pathway (one-step experiment), i.e., when the molecules are deposited onto the sample kept at 320 K. This pathway dependence demonstrates that nonequilibrium structures are involved. Our results are corroborated by kinetic Monte Carlo simulations, which reveal the same pathway-dependent structures as those in the experiments. Based on the simulations, we identify the barrier for freely diffusing molecules to jump from the first into the second layer (ascension barrier) as key for the formation of the different island morphologies. The second ingredient to arrive at different islands is that edge diffusion rates for single-layer and double-layer islands differ. While edge diffusion is enabled for single-layer islands, it is greatly suppressed in the case of double-layer islands (essentially due to additional bonds formed with molecules in the second layer). Thus, a given island shape is effectively stabilized when molecules can jump into the second layer. In essence, allowing the molecules to ascend into the second layer provides a means to stabilize the prepared molecular islands. Our work illustrates how different preparation protocols can be used to enhance the structural variability of molecular structure formation on surfaces.

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Structure Formation of C₆₀ on Insulating CaF₂ Substrates: Matching Experiments with Simulations

Cited by 2 publications

References 58 publications

FandMcenters in alkali halides: A theoretical study applying self-consistent dielectric-dependent hybrid density functional theory

FandMcenters in alkali halides: A theoretical study applying self-consistent dielectric-dependent hybrid density functional theory

Nonequilibrium Structures of C₆₀ on CaF₂(111): Exploring Structural Variability by Different Sample Preparation Pathways

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Structure Formation of C60 on Insulating CaF2 Substrates: Matching Experiments with Simulations

Cited by 2 publications

References 58 publications

FandMcenters in alkali halides: A theoretical study applying self-consistent dielectric-dependent hybrid density functional theory

FandMcenters in alkali halides: A theoretical study applying self-consistent dielectric-dependent hybrid density functional theory

Nonequilibrium Structures of C60 on CaF2(111): Exploring Structural Variability by Different Sample Preparation Pathways

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Structure Formation of C₆₀ on Insulating CaF₂ Substrates: Matching Experiments with Simulations

Nonequilibrium Structures of C₆₀ on CaF₂(111): Exploring Structural Variability by Different Sample Preparation Pathways