Abstract:Insufficient separation of photogenerated electron−hole and feeble CO 2 activation remain the main obstacles in the access to high-performance CO 2 reduction nowadays. Single-atom active sites engineering could be an efficient method through simultaneously promoting charge separation and CO 2 activation. Herein, a model of Bi 4 O 5 I 2 with single-atom Fe implanting and accompanying Bi decorating on surface is proposed to boost the performance. The single-atom Fe implantation decreases the value of surface wor… Show more
“…The differential charge densities of Fe-SA/WO 2.72– x with N 2 adsorption clearly show that the N 2 molecule obtains electrons from WO 2.72– x and is activated (Figure e). In addition, the pictures of the electron localization function (ELF, Figure f,g) indicate that when the Fe single atom is anchored on the WO 2.72– x surface, there is delocalization of electrons across the Fe–O bond (Figure S13), which denotes high covalency favorable to the state transition of interfacial electrons and acceleration of charge transfer . The above results indicate that an electron transfer channel is created between the Fe-SA/WO 2.72– x surface and the adsorbed N 2 , enabling the Fe single atom to be the active site for N 2 activation.…”
In
the design of photocatalysts for ammonia synthesis, the construction
of effective nitrogen (N2) adsorption and activation sites
is critical. Herein, Fe single atoms were effectively fixed on the
surfaces of WO2.72–x
nanowires.
Electronic interactions between single Fe atoms and WO2.72–x
resulted in a d-band center shift
toward the Fermi level and thus enhancement of N2 bonding
with the catalyst surface. The studies of differential charge density
and electron localization reveal that there is enhanced electron transfer
from Fe-SA/WO2.72–x
to the adsorbed
N2, signifying that Fe single atoms are active centers
for N2 activation. Benefiting from electronic interactions,
the optimized catalyst shows a NH4
+ generation
rate of 186.5 μmol g–1 h–1 during photocatalytic N2 reduction.
“…The differential charge densities of Fe-SA/WO 2.72– x with N 2 adsorption clearly show that the N 2 molecule obtains electrons from WO 2.72– x and is activated (Figure e). In addition, the pictures of the electron localization function (ELF, Figure f,g) indicate that when the Fe single atom is anchored on the WO 2.72– x surface, there is delocalization of electrons across the Fe–O bond (Figure S13), which denotes high covalency favorable to the state transition of interfacial electrons and acceleration of charge transfer . The above results indicate that an electron transfer channel is created between the Fe-SA/WO 2.72– x surface and the adsorbed N 2 , enabling the Fe single atom to be the active site for N 2 activation.…”
In
the design of photocatalysts for ammonia synthesis, the construction
of effective nitrogen (N2) adsorption and activation sites
is critical. Herein, Fe single atoms were effectively fixed on the
surfaces of WO2.72–x
nanowires.
Electronic interactions between single Fe atoms and WO2.72–x
resulted in a d-band center shift
toward the Fermi level and thus enhancement of N2 bonding
with the catalyst surface. The studies of differential charge density
and electron localization reveal that there is enhanced electron transfer
from Fe-SA/WO2.72–x
to the adsorbed
N2, signifying that Fe single atoms are active centers
for N2 activation. Benefiting from electronic interactions,
the optimized catalyst shows a NH4
+ generation
rate of 186.5 μmol g–1 h–1 during photocatalytic N2 reduction.
“…For instance, Jin et al. proposed SAPs with Fe SAs implanted into the surface of Bi 4 O 5 I 2 (Bi 4 O 5 I 2 -Fe30) ( Jin et al., 2021 ). As such, Fe SAs were considered as the dopant to replace the Biatoms in Bi 4 O 5 I 2 , which generated impurity energy levels within the bandgap of Bi 4 O 5 I 2 , leading to a broadened light-harvesting range toward the Bi 4 O 5 I 2 -Fe30 SAPs.…”
Section: Current Research Progress On Sapsmentioning
confidence: 99%
“… Figure 6 Effect of single-atom modification on the electronic structure of photocatalysts (A–I) Bi 4 O 5 I 2 and Bi 4 O 5 I 2 -Fe30 of (A) UV-Vis absorption spectra, (B) Tauc plot, (C) Mott-Schottky plots, (D) XPS valence band spectroscopy, (E) DFT calculation for the band structure, and (F) DOS plots. Reproduced with permission from Ref ( Jin et al., 2021 ). Copyright 2021, American Chemical Society.…”
Section: Current Research Progress On Sapsmentioning
“…Huge efforts have been made worldwide to tackle the greenhouse effect from carbon emission. − Reduction of CO 2 , one of the major carbon emissions, to useful chemicals, such as CO, CH 4 , CH 3 OH, and HCOOH, has been of great interest in recent years. − Among the products, selective and highly efficient reduction of CO 2 to CO is of particular interest because of its favorable reaction kinetics in the reduction process and the value of CO in the chemical industries. , Typical photocatalysts used for CO 2 reduction, such as metal oxides and metal sulfides, could generate photoelectrons via photoirradiation because of the semiconductive properties; however, insufficient electron–hole separation and low light absorption volume still hinder their practical performance. − Though noble metal nanoparticles were introduced to boost the electron–hole separation efficiency of these nano-semiconductors, , the low utilization efficiency of noble metals still restricts their practical application. Compared with nanostructured semiconductors, carbon is abundant, excels in light absorption, and is usually used as a promoter in photocatalysts. , In recent years, the carbonaceous promoters for photocatalysts, especially graphene, have attracted a lot of interest because of their physical and chemical properties. − However, fine-tuning the electronic structure of graphene to effectively drive the photoreduction of CO 2 remains a challenge.…”
Section: Introductionmentioning
confidence: 99%
“…8,9 Typical photocatalysts used for CO 2 reduction, such as metal oxides and metal sulfides, could generate photoelectrons via photoirradiation because of the semiconductive properties; however, insufficient electron−hole separation and low light absorption volume still hinder their practical performance. 10−12 Though noble metal nanoparticles were introduced to boost the electron−hole separation efficiency of these nano-semi-conductors, 13,14 the low utilization efficiency of noble metals still restricts their practical application. Compared with nanostructured semiconductors, carbon is abundant, excels in light absorption, and is usually used as a promoter in photocatalysts.…”
The
reduction of CO2 to useful chemicals by solar irradiation
has been of great interest in recent years to tackle the greenhouse
effect. Compared with inorganic metal oxide particles, carbonaceous
materials, such as graphene, are excellent in light absorption; however,
they lack in activity and selectivity because of the challenge to
manipulate the band gap and optimize the electron–hole separation,
which drives the photoreduction process. In this work, inspired by
the delicate natural plant leaf structure, we fabricated orderly stacked
graphene nanobubble arrays with nitrogen dopant for the coordination
of noble metal atoms to mimic the natural photoreduction process in
plant leaves. This graphene metamaterial not only mimics the optical
structure of leaf cells, which scatter and absorb light efficiently,
but also drives the CO2 reduction via nitrogen coordinated
metal atoms as the chlorophyll does in plants. Our characterizations
show that the band gap of nitrogen-doped graphene could be precisely
tailored via substitution with different noble metal atoms on the
doped site. The noble atoms coordinated on the doped site of graphene
metamaterial not only enlarge the light absorption volume but also
maximize the utilization of noble metals. The bionic optical leaf
metamaterial coordinated with Au atoms exhibits high CO productivity
up to 11.14 mmol gcat
–1 h–1 and selectivity to 95%, standing as one of the best catalysts among
the carbonaceous and metal-based catalysts reported to date. This
catalyst also maintained a high performance at low temperatures, manifesting
potential applications of this bionic catalyst at polar regions to
reduce greenhouse gases.
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