Structure and dynamics of 
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 molecules on Au(111)

Shin, Heekeun; Schwarze, A.; Diehl, Renee D.; Pussi, Katariina; Colombier, A.; Gaudry, Émilie; Ledieu, J.; McGuirk, G. M.; Loli, L. N. Serkovic; Fournée, V.; Wang, L. L.; Schull, Guillaume; Berndt, Richard

doi:10.1103/physrevb.89.245428

Cited by 42 publications

(72 citation statements)

References 38 publications

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“…12, 244 In contrast, when the bonding energy is of the same order of magnitude as the diffusion energy, the adsorbate behavior on the surface is more sensitive to temperature effects, and an equilibrium exists between a 2D gas phase on the surface and the gas phase itself. Although surface diffusion of atoms and of small molecules, such as carbon monoxide, is well understood (and often follows a simple single particle hopping model), the problem is significantly more complex in the case of larger molecules 245 because they span several surface adsorption sites, 246 deform during diffusion, 247 interact with surface defects, 248 can induce local surface reconstruction (see below), 249 can diffuse only in specific directions, 250 and can be immobilized or highly mobile depending on the orientation with respect to the surface atomic lattice, 251 among other effects.…”

Section: Diffusion Barriersmentioning

confidence: 99%

Bicomponent Supramolecular Architectures at the Vacuum–Solid Interface

et al. 2017

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This review aims at giving the readers the basic concepts needed to understand two-dimensional bimolecular organizations at the vacuum–solid interface. The first part describes and analyzes molecules–molecules and molecules–substrates interactions. The current limitations and needs in the understanding of these forces are also detailed. Then, a critical analysis of the past and recent advances in the field is presented by discussing most of the key papers describing bicomponents self-assembly on solid surface in an ultrahigh vacuum environment. These sections are organized by considering decreasing molecule–molecule interaction strengths (i.e. starting from strong directional multiple H bonds up to weaker nondirectional bonds taking into account the increasing fundamental role played by the surface). Finally, we conclude with some research directions (predicting self-assembly, multi-components systems, and nonmetallic surfaces) and potential applications (porous networks and organic surfaces).

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Section: Diffusion Barriersmentioning

confidence: 99%

Bicomponent Supramolecular Architectures at the Vacuum–Solid Interface

et al. 2017

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“…For an in-depth understanding, it is advantageous to use a scanning tunneling microscope (STM) for imaging because it provides information about the local environment of each individual molecule, which is important since the molecular properties might differ locallydue to defects, step edges, or different areas of a surface reconstruction [4,5]. For instance, individual C 60 molecules were found to change between dark and bright appearances in STM images, caused by the diffusion of surface [6] or bulk [7] vacancies, charge transfer between molecule and surface [8], or adsorption on small metal islands [9].Adatoms are known to diffuse on close-packed metal surfaces if the thermal energy is sufficient for their detachment from step edges [10]. When molecules are adsorbed on such a surface, the adatoms can interact with and even be trapped by molecules [11][12][13][14][15], leading to characteristic metallic nanostructures that reflect the molecular shape [16][17][18].…”

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confidence: 99%

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confidence: 99%

Observing single-atom diffusion at a molecule-metal interface

et al. 2016

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The dynamics at the interface between a close-packed porphyrin monolayer and Au(111) is investigated by time-dependent scanning tunneling microscopy, detecting the motion of single-interface adatoms in real space. Imaging sequences reveal predominant switching of the molecular appearance in adjacent molecules, pointing to a spatial correlation that is consistent with adatom diffusion from one molecule to the next. In some cases, the number of switching molecules is drastically increased, indicating collective switching events. In addition to the thermally induced motion of adatoms at the interface, also voltage pulses from the microscope tip can induce the process-revealing different yields in agreement with the model of adatom hopping. DOI: 10.1103/PhysRevB.94.035416 The interface between organic molecules and metal substrates plays a key role for many properties that are important, for instance, in catalytically driven reactions [1,2] and for charge transport [3]. The study of such systems gives detailed insight into fundamental processes that take place at an organic-inorganic interface. For an in-depth understanding, it is advantageous to use a scanning tunneling microscope (STM) for imaging because it provides information about the local environment of each individual molecule, which is important since the molecular properties might differ locallydue to defects, step edges, or different areas of a surface reconstruction [4,5]. For instance, individual C 60 molecules were found to change between dark and bright appearances in STM images, caused by the diffusion of surface [6] or bulk [7] vacancies, charge transfer between molecule and surface [8], or adsorption on small metal islands [9].Adatoms are known to diffuse on close-packed metal surfaces if the thermal energy is sufficient for their detachment from step edges [10]. When molecules are adsorbed on such a surface, the adatoms can interact with and even be trapped by molecules [11][12][13][14][15], leading to characteristic metallic nanostructures that reflect the molecular shape [16][17][18]. In addition to these self-organized structures, manipulation of single adatoms has been used to bring them in contact with molecules [19,20]. So far, real space studies of the molecule-surface interaction have been done mainly under static conditions [21,22] or focus on the lateral diffusion of molecules on surfaces [23][24][25]. Here, we report the dynamic behavior at the molecule-metal interface by observing the motion of individual gold adatoms underneath a molecular monolayer on Au(111) in time.As a molecular system we have chosen tetrabromophenylporphyrin [Br 4 TPP; Fig. 1(a) The appearance of our molecules strongly depends on the applied bias voltage: At −0.5 V all molecules appear at a similar height, while at around −1 V two dark and one bright molecular appearances can be found [ Fig. 1(b)]. The two dark molecules could be identified as two tautomers without a gold adatom, while bright molecules have a single gold adatom underneath, causing the shift i...

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“…C 60 can eject different number of substrate atoms and generate vacancies of different sizes, i.e., a single vacancy on Al, 17,18 Pt, 19,20 Ag, 21,22 and Au [23][24][25] (111) surfaces while a seven-atom nanopit on Cu(111) 26,27 . Here using density functional theory 28,29 are linear combinations generated from these two phases for 1.20ML < θ < 1.33ML, as θ is increased gradually.…”

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confidence: 99%

“…DFT-LDA calculations have been shown to describe well the C 60 /metal interfaces, to explain successfully the puzzle in work function change on noble metal surfaces after C 60 adsorption, 32,33 and to predict the energetics of the surface reconstructions induced by C 60 , 20,21 and even the different orientations of C 60 at the single vacancy on Ag(111) and Au(111) . 25 To estimate the van der Waals (vdW) interaction in the system 38,47 , DF1-optPBE has been used to check key results. We use a 400 eV kinetic energy cut-off, 12 Å vacuum layer, and ( …”

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confidence: 99%