Synthesis of MnO 2 -Ag Nanojunctions with Plasmon-Enhanced Photocatalytic and Photothermal Effects for Constructing Rewritable Mono-/Multi-Color Fabrics.

Semiconductor-mediated photoreversible color switching systems (PCSSs) have great potential to replace traditional photochromic materials, and the key is to obtain semiconductors with unique photocatalytic and photothermal features. Herein, we have developed MnO 2 -Ag nanojunctions with plasmon-enhanced photocatalytic and photothermal effects for PCSSs. MnO 2 -Ag nanojunctions are solvothermally synthesized with Mn(CH 3 COO) 3 , KMnO 4 , and AgNO 3 in diethylene glycol as precursors, and they are composed of MnO 2 nanoparticles (∼30 nm) that are decorated by Ag nanodots (∼6 nm). The presence of Ag confers an enhanced visible photoabsorption with a narrow band gap for MnO 2 ( E g = 1.82 eV) and a weak/broad photoabsorption tail (∼875 nm) compared to that of pure MnO 2 (2.45 eV, ∼625 nm). By coupling MnO 2 -Ag nanojunctions with various redox dyes, some PCSS inks can be obtained, and especially, the inks containing hydroxyethyl cellulose could be used to prepare rewritable fabrics. When inks and fabrics are irradiated by 475 nm light, rapid discoloration can occur, resulting from the photocatalytic reduction of the dye. Contrarily, the irradiation of 808 nm light promotes the rapid recoloration since Ag nanodots with plasmonic effects in the nanojunctions can absorb light to generate heat, which facilitates the oxidization of leuco dyes in air. Consequently, remote printing of figures was attained on the rewritable fabrics via 475 nm light illumination, and then, the erasure was performed by 808 nm light illumination in an O 2 atmosphere, with high reversibility and cycling stability. Therefore, MnO 2 -Ag nanojunctions have tremendous promise for rewritable media, and the introduction of metal-semiconductor junctions as a nanophotocatalyst offers new insights for PCSSs.