Materials Research and Technology Department and ‡Environmental Research and Innovation Department, Luxembourg Institute of Science and Technology , 5 avenue des Hauts-Fourneaux, L-4362 Esch-sur-Alzette, Luxembourg.
ACS Appl Mater Interfaces. 2017 Nov 29;9(47):41200-41209. doi: 10.1021/acsami.7b10904. Epub 2017 Nov 15.
UV and visible light photocatalytic composite Pt and Au-TiO coatings have been deposited on silicon and glass substrates at low temperature using a hybrid ECWR-PECVD/MS-PVD process. Methylene blue, stearic acid, and sulfamethoxazole were used as dye, organic, and antibiotic model pollutants, respectively, to demonstrate the efficiency of these nanocomposite coatings for water decontamination or self-cleaning surfaces applications. Raman investigations revealed the formation of anatase polymorph of TiO in all synthesized coatings with a shifting of the main vibrational mode peak to higher wavenumber in the case of Au-TiO coating, indicating an increase number of crystalline defects within this coating. Because of the difference of the chemical potentials of each of the investigated noble metals, the sputtered metal layers exhibit different morphology. Pt sputtered atoms, with high surface adhesion, promote formation of a smooth 2D layer. On the other hand, Au sputtered atoms with higher cohesive forces promote the formation of 5-10 nm nanoparticles. As a result, the surface plasmon resonance phenomenon was observed in the Au-TiO coatings. UV photoactivity of the nanocomposite coatings was enhanced 1.5-3 times and 1.3 times for methylene blue and stearic acid, respectively, thanks to the enhancement of electron trapping in the noble metal layer. This electron trapping phenomenon is higher in the Pt-TiO coating because of its larger work function. On the other hand, the enhancement of the visible photoactivity was more pronounced (3 and 7 times for methylene blue and stearic acid, respectively) in the case of Au-TiO thanks to the surface plasmon resonance. Finally, these nanocomposite TiO coatings exhibited also a good ability for the degradation of antibiotics usually found in wastewater such as sulfamethoxazole. However, a complementary test have showed an increase of the toxicity of the liquid medium after photocatalysis, which could be due the presence of sulfamethoxazole's transformation byproducts.
采用 ECWR-PECVD/MS-PVD 混合工艺,在低温下将 Pt 和 Au-TiO 光催化复合涂层沉积在硅和玻璃基底上。以亚甲基蓝、硬脂酸和磺胺甲恶唑分别作为染料、有机和抗生素模型污染物,以证明这些纳米复合涂层在水净化或自清洁表面应用方面的效率。拉曼研究表明,所有合成涂层中均形成了锐钛矿型 TiO,在 Au-TiO 涂层中,主要振动模式峰向更高波数移动,表明该涂层中晶态缺陷数量增加。由于所研究的贵金属的化学势不同,溅射的金属层表现出不同的形态。Pt 溅射原子具有高表面附着力,促进了二维平滑层的形成。另一方面,具有较高内聚力的 Au 溅射原子促进了 5-10nm 纳米颗粒的形成。因此,在 Au-TiO 涂层中观察到表面等离子体共振现象。由于在贵金属层中电子捕获的增强,纳米复合涂层的光催化活性分别增强了 1.5-3 倍和 1.3 倍,用于亚甲基蓝和硬脂酸。由于其更大的功函数,Pt-TiO 涂层中的这种电子捕获现象更高。另一方面,由于表面等离子体共振,在 Au-TiO 情况下,可见光活性的增强更为明显(亚甲基蓝和硬脂酸分别为 3 倍和 7 倍)。最后,这些纳米复合 TiO 涂层对通常在废水中发现的抗生素(如磺胺甲恶唑)的降解也表现出良好的能力。然而,补充测试表明,光催化后液体介质的毒性增加,这可能是由于磺胺甲恶唑的转化副产物的存在。