Quantum wire and dot formation by chemical vapor deposition and molecular layer deposition of one-dimensional conjugated polymer

Yoshimura, Tetsuzo; Tatsuura, Satoshi; Sotoyama, Wataru; Matsuura, Akira; Hayano, Tomoaki

doi:10.1063/1.106681

Cited by 97 publications

(53 citation statements)

References 4 publications

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“…This is consistent with work by Yoshimura et al, 20 who found in optical measurements an absorption peak energy of 4.9 eV for TDA and and 2.9 eV for a copolymer of TDA and DAB. From ab initio calculations, Onipko et al found a gap value of 5 eV for 4-ATP and 4.1 eV for ATD.…”

Section: Discussionsupporting

confidence: 82%

Tunneling spectroscopy study and modeling of electron transport in small conjugated azomethine molecules

et al. 2000

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Scanning tunneling spectroscopy results are presented on oriented monolayer films of conjugated phenylbased molecules self-assembled on gold. Three related molecules of different lengths are investigated. The molecules do not show resonances in electron transmission at least up to 1.5 V. We model the experiments successfully by the molecules acting as a potential barrier to electron transmission. The potential barrier is trapezoidal when the molecule has a permanent dipole moment ͑normal to the gold surface͒, in agreement with the asymmetric I(V) curves. For 2 V bias and larger, the film is modified by the measurement, which prevents measurements of possible resonances at higher energies.

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Section: Discussionsupporting

confidence: 82%

Tunneling spectroscopy study and modeling of electron transport in small conjugated azomethine molecules

et al. 2000

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“…Traditionally, ALD has been used to fabricate rather simple well-known inorganic materials, such as binary oxides and nitrides. The range of materials was fundamentally broadened by experiments producing organic polymers in the 1990s by a variant of ALD, now commonly known as molecular layer deposition (MLD), named after the molecular layer-by-layer fashion the film grows during the deposition [5–9]. Then – most excitingly – in the late 2000s the two techniques, ALD and MLD, were combined to produce inorganic–organic hybrid materials (Fig.…”

Section: Introductionmentioning

confidence: 99%

Organic and inorganic–organic thin film structures by molecular layer deposition: A review

Sundberg¹,

Karppinen²

2014

Beilstein J. Nanotechnol.

287

346

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SummaryThe possibility to deposit purely organic and hybrid inorganic–organic materials in a way parallel to the state-of-the-art gas-phase deposition method of inorganic thin films, i.e., atomic layer deposition (ALD), is currently experiencing a strongly growing interest. Like ALD in case of the inorganics, the emerging molecular layer deposition (MLD) technique for organic constituents can be employed to fabricate high-quality thin films and coatings with thickness and composition control on the molecular scale, even on complex three-dimensional structures. Moreover, by combining the two techniques, ALD and MLD, fundamentally new types of inorganic–organic hybrid materials can be produced. In this review article, we first describe the basic concepts regarding the MLD and ALD/MLD processes, followed by a comprehensive review of the various precursors and precursor pairs so far employed in these processes. Finally, we discuss the first proof-of-concept experiments in which the newly developed MLD and ALD/MLD processes are exploited to fabricate novel multilayer and nanostructure architectures by combining different inorganic, organic and hybrid material layers into on-demand designed mixtures, superlattices and nanolaminates, and employing new innovative nanotemplates or post-deposition treatments to, e.g., selectively decompose parts of the structure. Such layer-engineered and/or nanostructured hybrid materials with exciting combinations of functional properties hold great promise for high-end technological applications.

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“…One of the tailored nanoscale structures constructed by MLD is the organic MQDs such as polymer MQDs [5,14,32] and molecular MQDs [8,20]. The polymer MQDs are polymer wires containing quantum dots, and the molecular MQDs are molecular wires containing quantum dots.…”

Section: Organic Multiple Quantum Dots (Mqds)mentioning

confidence: 99%

“…As shown in Figure 8.11, the absorption peak shifts toward the higher energy side in the order of poly-AM quantum wire, OTPTPT, OTPT, and OT, namely, with decreasing the quantum dot length. The peak positions are plotted by squares in The quantum-dot-length dependence of the absorption peak position, which was derived from the quantum-confined electron model, is also presented in Figure 8.12 by a dotted line [5]. The calculation was carried out using the following expression for the energy of electrons confined in a quantum dot with infinite potential barrier heights:…”

Section: Quantum Confinement Effect In Polymer Mqdsmentioning

confidence: 99%

Thin‐Film Molecular Nanophotonics

Yoshimura

2015

Photonics

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Quantum wire and dot formation by chemical vapor deposition and molecular layer deposition of one-dimensional conjugated polymer

Cited by 97 publications

References 4 publications

Tunneling spectroscopy study and modeling of electron transport in small conjugated azomethine molecules

Tunneling spectroscopy study and modeling of electron transport in small conjugated azomethine molecules

Organic and inorganic–organic thin film structures by molecular layer deposition: A review

Thin‐Film Molecular Nanophotonics

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