Cyano-Substituted Triptycene-Based Monolayers on Au(111): Tripodal Adsorption, Dipole Engineering, and Charge Transfer

Das, Saunak; Asyuda, Andika; Shoji, Yoshiaki; Kosaka, Atsuko; Fukushima, Takanori; Zharnikov, Michael

doi:10.1021/acs.jpcc.1c05618

Cited by 12 publications

(30 citation statements)

References 80 publications

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“…We think that this statement is also applicable to the acene backbones in general as well as to oligophenylene and oligo(phenylene ethynylene) backbones, popular in molecular electronics. The only exceptions are probably SAMs with extended aromatic building blocks in the backbone and very high molecular order, for which a considerable lateral band transport, similar to that in organic semiconductors, takes place. , Note that even a lateral linkage of individual aromatic backbones by an aliphatic bridge, as it occurs in the triptycene-based monolayers, does not result in a noticeable increase in τ ET compared to the value for the nonlinked backbones …”

Section: Resultsmentioning

confidence: 99%

“…21,22 Note that even a lateral linkage of individual aromatic backbones by an aliphatic bridge, as it occurs in the triptycene-based monolayers, does not result in a noticeable increase in τ ET compared to the value for the nonlinked backbones. 66 Note also that even though we do not have strict evidence for an intermolecular mixture in the binary NC-Nap/C6 SAMs, which is essential for the conclusions, general considerations and previous results with binary SAMs do support our assumption. First, the molecular exchange procedure, intentionally chosen for the preparation of the binary SAMs (see section 2 for the technical details), is favorable for intermolecular mixture in contrast to coadsorption, which sometimes results in phase segregation.…”

Section: Thementioning

confidence: 99%

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Probing Matrix Effects in the Course of Electron Transfer across a Self-Assembled Monolayer

et al. 2022

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Charge transport across a self-assembled monolayer (SAM) can involve either individual molecules only (throughbond model) or also intermolecular pathways (through-film model or matrix effects). In this context, we test a possible involvement of the latter pathways in the electron transfer (ET) across a model, nitrile-terminated naphthalene-2-thiolate (NC-Nap) SAM on Au(111). For this purpose, we apply the so-called core-holeclock approach in the framework of resonant Auger electron spectroscopy, allowing the measurement of the characteristic ET time from the nitrile tail group of NC-Nap to the substrate. The efficiency of possible intermolecular pathways depends on the electronic coupling between individual NC-Nap molecules, which was progressively reduced by mixing NC-Nap with short-chain alkanethiolates in binary SAMs. It turns out that the value of the characteristic ET time, estimated as 24 ± 4 fs for the reference, single-component NC-Nap SAM, does not vary noticeably in the binary monolayers, independent of the NC-Nap content. This means that the matrix effects play a negligible role for ET dynamics in the given model SAM, strongly favoring the through-bond CT model.

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Section: Resultsmentioning

confidence: 99%

Section: Thementioning

confidence: 99%

Probing Matrix Effects in the Course of Electron Transfer across a Self-Assembled Monolayer

et al. 2022

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“…Fukushima et al have recently reported the formation of SAMs from tripodal triptycene derivatives such as Trip (Figure a). − The molecular tripods, which are structurally rigid and capable of forming uniform monolayers with dense molecular packing by a simple solution process, are expected to serve as a new platform for isolating molecules at solid–liquid interfaces, eliminating the fluctuation and orientation problems of conventional alkanethiol SAMs.…”

Section: Introductionmentioning

confidence: 99%

Single-Molecule Observation of Redox Reactions Enabled by Rigid and Isolated Tripodal Molecules

et al. 2022

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Tracking various chemical reactions, including electrochemical and photochemical reactions at the single-molecule level, is expected to yield a great deal of knowledge from both fundamental and applied aspects. In this study, we report on a methodology to track the electronic-state changes of redox reactions at the single-molecule level by using electrochemical scanning tunneling microscopy (EC-STM). EC-STM is powerful for single-molecule analysis of redox reactions, but previous studies have shown difficulties separating the structural and electronic contributions due to orientational changes during the redox reaction. Here, we visualize the electronic-state changes of a single ferrocene associated with redox reactions using EC-STM by synthesizing and fabricating a monolayer of structurally rigid tripodal molecules based on triptycene, which act as ideal anchors to preserve a constant distance between the electrode and the ferrocene moieties. This methodology paves the way for versatile single-molecule measurements of important phenomena at the solid−liquid interface, such as photochemistry and heterogeneous catalysis.

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“…Accordingly, the best orientational order and the smallest molecular inclination are observed for the sample prepared at the elevated temperature and post-annealed at 100 °C. The respective average molecular tilt angle of ∼32.5°is somewhat high as compared to the SAMs of thiolate-anchored triptycenes on Au(111) and Ag(111), 34,36,37 but still reasonable. In view of the moderate roughness of the ITO substrates (see Section 2 for the details), the most likely reason for such a high angle is the possible chemical heterogeneity of the substrate surface (on the atomic scale), resulting in a certain heterogeneity of the bonding configurations as discussed above.…”

Section: Discussionmentioning

confidence: 84%

“…Self-assembled monolayers (SAMs) represent a key element of modern nanotechnology finding application in frontier technology areas such as organic/hybrid solar cells, organic field effect transistors, − electrochromic devices, sensors, , molecular electronics, − etc. SAMs are generally comprised of rod-like molecules bearing an anchoring group that binds to a specific substrate and a functional tail group constituting the SAM-ambient interface and, along with other parts of the molecules, redefining the physicochemical properties of the substrate. ,, Along with this most frequently used design concept involving a single anchoring group and monodentate bonding to the substrate, molecules with complex or multiple anchoring groups having potentially dipodal, tripodal, or tetrapodal bonding configurations were designed. − Such molecules bear the advantage of yielding more robust SAMs with improved electronic coupling to the substrate and flexible control over the density of the tail groups. − Among different multidentate configurations, molecular tripods, − including in particular triptycene derivatives that can form SAMs on a variety of metal substrates, − gain particular attention. The triptycene scaffold consists of three phenyl rings, which are disposed at a dihedral angle of 120° relative to each other.…”

Section: Introductionmentioning

confidence: 99%

Triptycene-Based Tripodal Self-Assembled Monolayer on Indium Tin Oxide

et al. 2023

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The monomolecular assembly of 1,8,13-tricarboxytriptycene (Trip-CA) on a test oxide substrate, represented by indium tin oxide (ITO), was studied. For this purpose, X-ray photoelectron spectroscopy, near-edge X-ray absorption fine structure spectroscopy, contact angle goniometry, and work function measurements were used. The quality and the parameters of the resulting self-assembled monolayers (SAMs) were found to depend strongly on the preparation conditions, with an elevated preparation temperature (50 °C) and post-annealing at an optimal temperature (100 °C) being the most favorable factors. Analysis of the data favors a monodentate bonding configuration for individual CA groups of Trip-CA and a tripodal bonding mode for the molecules as a whole, even though a certain heterogeneity of bonding configurations cannot be excluded. The molecules exhibit a moderate orientational order with an average tilt angle of 32.5°. Because of the nonpolar character of the triptycene backbone, the decoration of ITO with Trip-CA does not result in a significant change of the work function, which speaks for the introduction of polar tail groups at the application of this platform to electrostatic interface engineering.

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Cyano-Substituted Triptycene-Based Monolayers on Au(111): Tripodal Adsorption, Dipole Engineering, and Charge Transfer

Cited by 12 publications

References 80 publications

Probing Matrix Effects in the Course of Electron Transfer across a Self-Assembled Monolayer

Probing Matrix Effects in the Course of Electron Transfer across a Self-Assembled Monolayer

Single-Molecule Observation of Redox Reactions Enabled by Rigid and Isolated Tripodal Molecules

Triptycene-Based Tripodal Self-Assembled Monolayer on Indium Tin Oxide

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