Self-assembled two-dimensional nanoporous molecular arrays and photoinduced polymerization of 4-bromo-4′-hydroxybiphenyl on Ag(111)

Shen, Qian; He, Jing; Zhang, Jia Lin; Wu, Kai; Xu, Guo Qin; Wee, Andrew Thye Shen; Chen, Wei

doi:10.1063/1.4906116

Cited by 24 publications

(23 citation statements)

References 49 publications

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“…In fact, most of the reactions described so far are initiated by thermal annealing which however often creates defects in the formed structures due to the increased diffusion of the precursors on the surface. In order to circumvent this problem, some work was reported where the polymerization was initiated by UVillumination 12,25,26,27,28 or current injection by means of an scanning tunnelling microscopy tip. 7,29,30,31 The main limitations of the so far created structures in view of future applications in nanoscale electronic and optical devices are (i) the use of metal substrates (for instance, leading to non-radiative quenching 32 ), (ii) the high number of defects in the formed covalent structures, and (iii) the side-products of some reactions which might remain on the substrate surface.…”

Section: Main Textmentioning

confidence: 99%

Micrometre-long covalent organic fibres by photoinitiated chain-growth radical polymerization on an alkali-halide surface

et al. 2018

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On-surface polymerization is a promising technique to prepare organic functional nanomaterials that are challenging to synthesize in solution, but it is typically used on metal substrates, which play a catalytic role. Previous examples on insulating surfaces have involved intermediate self-assembled structures, which face high barriers to diffusion, or annealing to higher temperatures, which generally causes rapid dewetting and desorption of the monomers. Here we report the photoinitiated radical polymerization, initiated from a two-dimensional gas phase, of a dimaleimide monomer on an insulating KCl surface. Polymer fibres up to 1 μm long are formed through chain-like rather than step-like growth. Interactions between potassium cations and the dimaleimide's oxygen atoms facilitate the propagation of the polymer fibres along a preferred axis of the substrate over long distances. Density functional theory calculations, non-contact atomic force microscopy imaging and manipulations at room temperature were used to explore the initiation and propagation processes, as well as the structure and stability of the resulting one-dimensional polymer fibres.

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Section: Main Textmentioning

confidence: 99%

Micrometre-long covalent organic fibres by photoinitiated chain-growth radical polymerization on an alkali-halide surface

et al. 2018

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“… 6 , 8 , 9 Heat, i.e., thermal energy, is the preferred stimulus for activation, but alternative activation modes have also been explored, for instance, a scanning tunneling microscope (STM) tip (via voltage pulses), 10 an electron beam, 11 or light. 12 …”

Section: Introductionmentioning

confidence: 99%

“… 29 Simultaneous C–Br and C–OH bond cleavage of hydroxyphenyl molecules on Ag(111) was triggered by UV light. 12 This led to the formation of biphenyl biradical species that assemble into porous networks, stabilized by interactions with substrate Ag atoms at 80 K. At RT, the same radical species couple to each other and form covalently linked polyphenylene chains.…”

Section: Introductionmentioning

confidence: 99%

“…Chemical bonds within adsorbed molecules have been dissociated using either the STM tip, 10 , 30 heat, 2 or light 12 or by a combination of voltage pulses from a STM tip and light. 31 , 32 The subsequent synthesis of covalently linked nanostructures is achieved by thermal activation 4 or without heating (i.e., at RT) in the case of photoactivated species.…”

Section: Introductionmentioning

confidence: 99%

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Thermal- vs Light-Induced On-Surface Polymerization

et al. 2021

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On-surface polymerization is a powerful bottom-up approach that allows for the growth of covalent architectures with defined properties using the two-dimensional confinement of a highly defined single-crystal surface. Thermal heating is the preferred approach to initiate the reaction, often via cleavage of halogen substituents from the molecular building blocks. Light represents an alternative stimulus but has, thus far, only rarely been used. Here, we present a direct comparison of on-surface polymerization of dibromo-anthracene molecules, induced either thermally or by light, and study the differences between the two approaches. Insight is obtained by a combination of scanning tunneling microscopy, locally studying the polymer shape and size, and X-ray photoelectron spectroscopy, which identifies bond formation by averaging over large surface areas. While the polymer length increases slowly with the sample heating temperature, illumination promotes only the formation of short covalent structures, independent of the duration of light exposure. Moreover, irradiation with UV light at different sample temperatures highlights the important role of molecular diffusion across the surface.

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“…In order to demonstrate that photo‐activation of chemical bonds can be a powerful approach to obtain long π‐conjugated polymers at room temperature, Shen et al. deposited the 4‐bromo‐4′‐hydroxy‐biphenyl molecule (Figure a), as starting precursor on a Ag(111) surface . α,ω‐disubstitued polyphenylenes are well‐known to lead to very long π‐conjugated polymers by thermally induced Ullmann cross‐coupling …”

Section: On‐surface Synthesis From Bond Photo‐dissociationmentioning

confidence: 99%

Photochemistry Highlights on On‐Surface Synthesis

2019

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On-surface chemistry is a promising way to achieve the bottomup construction of covalently-bonded molecular precursors into extended atomically-precise polymers adsorbed on surfaces. These polymers exhibit unprecedented physical or chemical properties which are of great interest for various potential applications. These nanostructures were mainly obtained in ultra-high vacuum (UHV) on noble metal single-crystal surfaces by thermal annealing as stimulus to provoke the polymerization with a catalytic role of the surface adatoms. Nevertheless, photons are also a powerful source of energy to induce the formation of covalent architectures, even if it is less-used on surfaces than in solution. In this minireview, we discuss the photo-induced on-surface polymerization from the basic mechanisms of photochemistry to the formation of extended polymers on different kinds of surfaces, which are characterized by scanning probe microscopies.[a] Prof.

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Self-assembled two-dimensional nanoporous molecular arrays and photoinduced polymerization of 4-bromo-4′-hydroxybiphenyl on Ag(111)

Cited by 24 publications

References 49 publications

Micrometre-long covalent organic fibres by photoinitiated chain-growth radical polymerization on an alkali-halide surface

Micrometre-long covalent organic fibres by photoinitiated chain-growth radical polymerization on an alkali-halide surface

Thermal- vs Light-Induced On-Surface Polymerization

Photochemistry Highlights on On‐Surface Synthesis

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