Surfactant-Mediated Incorporation of Poly(p-phenylene) into MoO₃

Abstract: Surfactant-mediated transport of insoluble, hydrophobic polymers can be exploited to produce a novel interleaved metal oxide/polymer composite containing poly(p-phenylene). The synthetic route is illustrated in the scheme, whereby a surfactant bilayer between the MoO3 layers is displaced by the PPP/surfactant dispersion. Subsequent heat treatment results in concomitant combustion of the surfactant and collapse of the oxide layers, thus entrapping the PPP chains as a polymer monolayer in the interlamellar gap.

“…It has applications as a catalyst in selective oxidation reaction, secondary batteries, information display systems, sensors, lubricants, photochromic, and electrochromic systems. [5] Compared with the bulk counterpart, a significantly large surface area and high aspect ratio could be expected in 1D nanostructure. A variety of techniques have been developed to control the morphologies of MoO 3 , for example the solvent thermal process, the electrochemical method, nanotubes templates, and acidification of ammonium heptamolybdate tetrahydrate.…”

Single‐Crystalline Molybdenum Trioxide Nanoribbons: Photocatalytic, Photoconductive, and Electrochemical Properties

“…It has applications as a catalyst in selective oxidation reaction, secondary batteries, information display systems, sensors, lubricants, photochromic, and electrochromic systems. [5] Compared with the bulk counterpart, a significantly large surface area and high aspect ratio could be expected in 1D nanostructure. A variety of techniques have been developed to control the morphologies of MoO 3 , for example the solvent thermal process, the electrochemical method, nanotubes templates, and acidification of ammonium heptamolybdate tetrahydrate.…”

Single‐Crystalline Molybdenum Trioxide Nanoribbons: Photocatalytic, Photoconductive, and Electrochemical Properties

“…Interest in layered crystal MoO 3 has been growing in recent years for its multifaced functional properties. Its applications include catalyst in selective oxidation reactions [3], secondary batteries [4], information display systems [5], sensors [6,7], lubricants [8], photochromic and electrochromic systems [9][10][11]. For these applications, large surface area has been found to be the efficient parameter.…”

Molybdenum trioxide nanostructures prepared by thermal oxidization of molybdenum

“…The increase of the interlayer spacing compared with that of pristine MoO 3 , 4.2 Å, corresponds to the dimensions of the phenyl ring ("width" and "thickness" are 5.3 and 3.3 Å) (21) , which suggests that the monolayer of polystyrene is still intercalated into the MoO 3 layers even after the heat treatment. This result implies that both the polystyrene and surfactant are intercalated into MoO 3 .…”

“…Wang et al (20) have prepared several polymer-Li x MoO 3 nanocomposites by the encapsulated precipitation. Nazar and co-workers (21) have reported the preparation of poly(p-phenylene) intercalated MoO 3 powders using a surfactant as a medium. Yao et al (22) …”

Preparation of Polystyrene and Surfactant Co-intercalated MoO3 Nano Hybrids and their VOC Gas Sensing Properties