Designing Nanoporous Membranes through Templateless Electropolymerization of Thieno[3,4-<i>b</i>]thiophene Derivatives with High Water Content

Thiam, El hadji Yade; Dramé, Abdoulaye; Sow, Salif; Sene, Aboubacary; Szczepanski, Caroline R.; Dieng, Samba Yandé; Guittard, Frédéric; Darmanin, Thierry

doi:10.1021/acsomega.9b00969

Cited by 20 publications

(33 citation statements)

References 36 publications

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“…84,85 Very recently, we have studied the influence of water on the surface morphology of electrodeposited polymers from thieno-[3,4-b]thiophene derivatives. 86,87 It has been demonstrated that with a significant amount of water in dichloromethane (dichloromethane saturated with water vs commercial dichloromethane), the surface morphology is drastically changed, e.g., from densely packed spherical particles to nanoporous membrane structures (with pores of d ∼ 100−300 nm) 86 or from smooth or treelike surfaces to hollow spherical or coral-like structures. 87 This is likely due to the formation of a large amount gas bubbles (O 2 and H 2 ) during electropolymerization in the dichloromethane/water system.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Exceptionally Strong Effect of Small Structural Variations in Functionalized 3,4-Phenylenedioxythiophenes on the Surface Nanostructure and Parahydrophobic Properties of Their Electropolymerized Films

et al. 2019

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Electropolymerization of electron-rich aromatics/heteroaromatics to form conducting polymers is an easy and powerful technique to form surfaces of different nanostructures and hydrophobicity/wettability. Understanding the factors governing the growth of the polymer nanostructures and controlling the surface morphology are the big challenges for the surface and materials science. In this paper, we report the design and synthesis of a series of 3,4-phenylenedioxythiophenes (PheDOTs) substituted at the benzene ring with 2-naphthylmethyl-, 1-naphthylmethyl-, and 9-anthracenylmethyl-groups (2Na-PheDOT, 1Na-PheDOT, and 9Ant-PheDOT). They have been electropolymerized in either potentiostatic or potentiodynamic conditions to form the polymer surfaces of different morphologies. Even small changes in the structure of PheDOT monomers by varying the side groups (2-/1-naphthyl- or 9-anthracenyl-) result in the formation of very different polymer surface nanostructures: from monodirectionally growing (one-dimensional) vertically aligned nanotubes for 2Na-PheDOT to ribbonlike nanostructures (two-dimensional) for 1Na-PheDOT, and a mixture of these two structures for 9Ant-PheDOT. Moreover, the surfaces of the p[2Na-PheDOT] polymer, electrodeposited from the monomer 2Na-PheDOT and the dimer (2Na-PheDOT) 2 (which have different solubilities and the reactivities on electropolymerization, but formally lead to the polymer of the same chemical structure), show very different nanostructures. In contrast to 2Na-PheDOT, which forms vertically aligned nanotubes of the polymer on the surface, the polymerization of (2Na-PheDOT) 2 leads to spherical particles [three-dimensional (3D)] when Bu4NClO4 is used as an electrolyte and a membrane structure with spherical holes (3D) in the case of more hydrophobic Bu4NPF6. The importance of water for gas bubble formation (O2 and H2) during electropolymerization and creation of the surface nanostructures has been demonstrated and discussed. The formation of these different nanostructures is accompanied by different wettability of the surface, from hydrophilic (with an apparent water droplet contact angle of θw ∼ 40–70°) to highly hydrophobic (θw up to 129–134°). The sticky, parahydrophobic surface formed from 1Na-PheDOT showed high adhesion to water, with no water droplets moving after inclination of the surface to 90° (rose-petal effect).

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Section: ■ Results and Discussionmentioning

confidence: 99%

Exceptionally Strong Effect of Small Structural Variations in Functionalized 3,4-Phenylenedioxythiophenes on the Surface Nanostructure and Parahydrophobic Properties of Their Electropolymerized Films

et al. 2019

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“…[33] The water content of the polymerization solvent also plays a huge part in the morphology of the resulting nanostructures, increasing their porosity. [34,35] The water indeed reacts during electropolymerization forming gas bubbles that can act as a softtemplate for the polymer deposition. It has been recently demonstrated that reverse micelles are formed in the electropolymerization solvent, and that these micelles also participate to the formation of a soft template, leading to porous nanostructures.…”

Section: Introductionmentioning

confidence: 99%

Designing Tunable Omniphobic Surfaces by Controlling the Electropolymerization Sites of Carbazole‐Based Monomers

Fradin

Guittard

Darmanin

2021

Macro Chemistry & Physics

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Carbazole‐based monomers are electrodeposited in dichloromethane with different water content and water pH in order to control the surface micro‐ and nanostructures. The presence of water makes the depositions more porous by the formation of a micellar soft template. Due to the presence of the free amine groups, the water acidity plays a role on the structure of the monomers by protonation, limiting their polymerization ways and thus controlling the morphology of the structures. The wetting properties are tuned either by deprotonation of the depositions, or fluorinated postgrafting. Surfaces reach superhydrophobic and oleophobic properties.

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“…Indeed, the nanotube formation is highly affected by H 2 O content because it changes the amount of released O 2 and/or H 2 bubbles. Indeed, the influence of H 2 O was already studied in the literature, [ 29,31 ] for example, by adding different amount of H 2 O and it was shown that the increase in H 2 O can often increase the number of nanotubes or other porous structures. [ 31 ]…”

Section: Introductionmentioning

confidence: 99%

“…Very recently, by a judicious choice in monomer and H 2 O content, the templateless electropolymerization process in organic solvent such as dichloromethane (CH 2 Cl 2 ) has been proposed as an efficient method to prepare extremely well‐controlled porous nanostructures such as vertically aligned nanotubes. [ 26–33 ] Trace H 2 O naturally present in solution are responsible for the formation of gas bubbles (O 2 and/or H 2 ). The method does not require any acid or surfactant but the monomer has to play the role of the surfactant in stabilizing gas bubbles during electropolymerization.…”

Section: Introductionmentioning

confidence: 99%

“…In the first one, substituted monomers of the thieno[3,4‐ b ]thiophene family are selected for their capacity to form nanotubular structures. [ 30–33 ] Three substituents of different hydrophobicity are chosen: pyrene, perfluorobutyl (C 4 F 9 ), and perfluorooctyl (C 8 F 17 ) chains. In the second strategy, a thieno[3,4‐ b ]thiophene monomer with a functional hydroxyl group (OH) is first electropolymerized before to graft perfluorinated chains by simple esterification reaction.…”

Section: Introductionmentioning

confidence: 99%

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Templateless Electrodeposition of Conducting Polymer Nanotubes on Mesh Substrates

Fradin

Celestini

Guittard

et al. 2020

Macro Chemistry & Physics

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Creating homogeneous nanostructures of complex substrates such as meshes remains a real challenge for practical applications. Here, a templateless elecropolymerization method is used to create conducting polymer nanotubes. Using thieno[3,4‐b]thiophene‐based monomers, nanotubes are obtained especially using dichloromethane saturated in water (CH2Cl2 + H2O) in order to release a high amount of O2 and H2 bubbles. Two strategies are used by direct electropolymerization or posttreatment by simple esterification reaction. By direct electropolymerization, the surface morphology is highly dependent on the used monomer. By contrast, by posttreatment it is possible to obtain the same structure and to change the surface energy during the posttreatment. With the last strategy, it is possible to reach superhydrophobic mesh with ultra‐low water adhesion and high oleophobic properties, even with short fluorinated chains (C4F9).

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Designing Nanoporous Membranes through Templateless Electropolymerization of Thieno[3,4-b]thiophene Derivatives with High Water Content

Cited by 20 publications

References 36 publications

Exceptionally Strong Effect of Small Structural Variations in Functionalized 3,4-Phenylenedioxythiophenes on the Surface Nanostructure and Parahydrophobic Properties of Their Electropolymerized Films

Exceptionally Strong Effect of Small Structural Variations in Functionalized 3,4-Phenylenedioxythiophenes on the Surface Nanostructure and Parahydrophobic Properties of Their Electropolymerized Films

Designing Tunable Omniphobic Surfaces by Controlling the Electropolymerization Sites of Carbazole‐Based Monomers

Templateless Electrodeposition of Conducting Polymer Nanotubes on Mesh Substrates

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