TY - JOUR
T1 - Plasmonic metal-organic framework nanocomposites enabled by degenerately doped molybdenum oxides
AU - Khan, Muhammad Waqas
AU - Zhang, Bao Yue
AU - Xu, Kai
AU - Mohiuddin, Md
AU - Jannat, Azmira
AU - Haque, Farjana
AU - Alkathiri, Turki
AU - Pillai, Naresha
AU - Wang, Yichao
AU - Reza, Syed Zahin
AU - Li, Jing
AU - Mulet, Xavier
AU - Babarao, Ravichandar
AU - Mahmood, Nasir
AU - Ou, Jian Zhen
PY - 2021
Y1 - 2021
N2 - Metal-organic frameworks (MOFs) nanocomposites are under the limelight due to their unique electronic, optical, and surface properties for various applications. Plasmonic MOFs enabled by noble metal nanostructures are an emerging class of MOF nanocomposites with efficient solar light-harvesting capability. However, major concerns such as poor photostability, sophisticated synthesis processes, and high fabrication cost are raised. Here, we develop a novel plasmonic MOF nanocomposite consisting of the ultra-thin degenerately doped molybdenum oxide core and the flexible iron MOF (FeMOF) shell through a hydrothermal growth, featuring low cost, facile synthesis, and non-toxicity. More importantly, the incorporation of plasmonic oxides in the highly porous MOF structure enhances the visible light absorbability, demonstrating improved photobleaching performances of various azo and non-azo dyes compared to that of pure FeMOF without the incorporation of oxidative agents. Furthermore, the nanocomposite exhibits enhanced sensitivity and selectivity towards NO2 gas at room temperature, attributed to the electron-rich surface of plasmonic oxides. This work possibly broadens the exploration of plasmonic MOF nanocomposites for practical and efficient solar energy harvesting, environmental remediation, and environmental monitoring applications.
AB - Metal-organic frameworks (MOFs) nanocomposites are under the limelight due to their unique electronic, optical, and surface properties for various applications. Plasmonic MOFs enabled by noble metal nanostructures are an emerging class of MOF nanocomposites with efficient solar light-harvesting capability. However, major concerns such as poor photostability, sophisticated synthesis processes, and high fabrication cost are raised. Here, we develop a novel plasmonic MOF nanocomposite consisting of the ultra-thin degenerately doped molybdenum oxide core and the flexible iron MOF (FeMOF) shell through a hydrothermal growth, featuring low cost, facile synthesis, and non-toxicity. More importantly, the incorporation of plasmonic oxides in the highly porous MOF structure enhances the visible light absorbability, demonstrating improved photobleaching performances of various azo and non-azo dyes compared to that of pure FeMOF without the incorporation of oxidative agents. Furthermore, the nanocomposite exhibits enhanced sensitivity and selectivity towards NO2 gas at room temperature, attributed to the electron-rich surface of plasmonic oxides. This work possibly broadens the exploration of plasmonic MOF nanocomposites for practical and efficient solar energy harvesting, environmental remediation, and environmental monitoring applications.
UR - https://hdl.handle.net/1959.7/uws:71353
U2 - 10.1016/j.jcis.2020.12.070
DO - 10.1016/j.jcis.2020.12.070
M3 - Article
SN - 0021-9797
VL - 588
SP - 305
EP - 314
JO - Journal of Colloid and Interface Science
JF - Journal of Colloid and Interface Science
ER -