posted on 2019-04-08, 00:00authored byWenjuan Liu, Hongbin Ge, Xiao Chen, Xiaolong Lu, Zhongwei Gu, Jinxing Li, Joseph Wang
With
compelling virtues of a large specific surface area, abundant
active sites, and fast interfacial transport, nanomaterials have been
demonstrated to be indispensable tools for water remediation applications.
Accordingly, micro/nanomotors made by nanomaterials would also benefit
from these properties. Though tuning the surface architecture on demand
becomes a hot topic in the field of nanomaterials, there are still
limited reports on the design of active surface architectures in chemically
driven tubular micro/nanomachines. Here, a unique architecture composed
of a fish-scale-like intercalated (FSI) surface structure and an active
layer with 5 nm nanoparticles is constructed, which composes of Fe2O3 and ramsdellite MnO2, Mn2O3, in the tubular micromotor using a versatile electrodeposition
protocol. Tailoring the electrodeposition parameters enables us to
modulate the active MnO2 surface structure on demand, giving
rise to a pronounced propulsion performance and catalytic activity.
Upon exposure to the azo-dye waste solution, the degradation efficacy
greatly raises by around 22.5% with FSI micromotor treatment when
compared to the normal compact motors, owing to the synergistic effect
between the Fe-related Fenton reaction and a large catalytic area
offered by the hierarchically rough inner surface. Such unique micromachines
with a large active surface area have great potential for environmental
and biomedical applications.