posted on 2016-06-09, 00:00authored byXiu Wang, Mingzhu Hong, Fuwei Zhang, Zanyong Zhuang, Yan Yu
Photocatalytic materials
for environmental remediation of organic
pollution and heavy metals require not only a strong visible light
response and high photocatalytic performance, but also the regeneration
and reuse of catalysts. In this work, a ternary hybrid structure material
of a nanoscale zero valent iron (Fe0) doped g-C3N4/MoS2 layered structure (GCNFM) was synthesized
by a facile strategy. Compared with the pure GCN, GCNM, and Fe-GCN,
the photodegradation efficiency of the GCNFM toward the RhB and Cr(VI)
under visible light is considerably enhanced, to 98.2% for RhB and
91.4% for Cr(VI), respectively. In addition, the reaction rate constants
(KRhB and KCr) of GCNFM are much higher than
those of GCN, GCNM, and Fe-GCN, which is attributed to the fact that
Fe0 and MoS2 composited with GCNM promote the
separation of photogenerated electron–hole pairs. Moreover,
with the loading of MoS2 and/or Fe0, the holes
could displace the •O2– as the
main reactive oxygen species in GCN. GCNFM maintains an efficient
degradation ability to both RhB and Cr(VI) after several cycles, in
spite of the fact that normally Fe0 will be consumed and
deactivated with the reduction proceeding as previously reported.
This suggests that the photogenerated electrons, in response, can
reduce the Fe(III)/Fe(II) to Fe0, inducing regeneration
and reuse of Fe0. We anticipate this work can provide a
good example for the design of efficient, visible light driven, and
recyclable photocatalysts for environmental remediation of both organic
pollution and heavy metals.