3 research outputs found
Spatial Distribution of Brønsted Acid Sites Determines the Mobility of Reactive Cu Ions in the Cu-SSZ-13 Catalyst during the Selective Catalytic Reduction of NO<sub><i>x</i></sub> with NH<sub>3</sub>
The formation of dimer-Cu species, which serve as the
active sites
of the low-temperature selective catalytic reduction of NOx with NH3 (NH3-SCR), relies
on the mobility of CuI species in the channels of the Cu-SSZ-13
catalysts. Herein, the key role of framework Brønsted acid sites
in the mobility of reactive Cu ions was elucidated via a combination
of density functional theory calculations, in situ impedance spectroscopy, and in situ diffuse reflectance
ultraviolet–visible spectroscopy. When the number of framework
Al sites decreases, the Brønsted acid sites decrease, leading
to a systematic increase in the diffusion barrier for [CuÂ(NH3)2]+ and less formation of highly reactive
dimer-Cu species, which inhibits the low-temperature NH3-SCR reactivity and vice versa. When the spatial distribution of
Al sites is uneven, the [CuÂ(NH3)2]+ complexes tend to migrate from an Al-poor cage to an Al-rich cage
(e.g., cage with paired Al sites), which effectively accelerates the
formation of dimer-Cu species and hence promotes the SCR reaction.
These findings unveil the mechanism by which framework Brønsted
acid sites influence the intercage diffusion and reactivity of [CuÂ(NH3)2]+ complexes in Cu-SSZ-13 catalysts
and provide new insights for the development of zeolite-based catalysts
with excellent SCR activity by regulating the microscopic spatial
distribution of framework Brønsted acid sites
Spatial Distribution of Brønsted Acid Sites Determines the Mobility of Reactive Cu Ions in the Cu-SSZ-13 Catalyst during the Selective Catalytic Reduction of NO<sub><i>x</i></sub> with NH<sub>3</sub>
The formation of dimer-Cu species, which serve as the
active sites
of the low-temperature selective catalytic reduction of NOx with NH3 (NH3-SCR), relies
on the mobility of CuI species in the channels of the Cu-SSZ-13
catalysts. Herein, the key role of framework Brønsted acid sites
in the mobility of reactive Cu ions was elucidated via a combination
of density functional theory calculations, in situ impedance spectroscopy, and in situ diffuse reflectance
ultraviolet–visible spectroscopy. When the number of framework
Al sites decreases, the Brønsted acid sites decrease, leading
to a systematic increase in the diffusion barrier for [CuÂ(NH3)2]+ and less formation of highly reactive
dimer-Cu species, which inhibits the low-temperature NH3-SCR reactivity and vice versa. When the spatial distribution of
Al sites is uneven, the [CuÂ(NH3)2]+ complexes tend to migrate from an Al-poor cage to an Al-rich cage
(e.g., cage with paired Al sites), which effectively accelerates the
formation of dimer-Cu species and hence promotes the SCR reaction.
These findings unveil the mechanism by which framework Brønsted
acid sites influence the intercage diffusion and reactivity of [CuÂ(NH3)2]+ complexes in Cu-SSZ-13 catalysts
and provide new insights for the development of zeolite-based catalysts
with excellent SCR activity by regulating the microscopic spatial
distribution of framework Brønsted acid sites
Spatial Distribution of Brønsted Acid Sites Determines the Mobility of Reactive Cu Ions in the Cu-SSZ-13 Catalyst during the Selective Catalytic Reduction of NO<sub><i>x</i></sub> with NH<sub>3</sub>
The formation of dimer-Cu species, which serve as the
active sites
of the low-temperature selective catalytic reduction of NOx with NH3 (NH3-SCR), relies
on the mobility of CuI species in the channels of the Cu-SSZ-13
catalysts. Herein, the key role of framework Brønsted acid sites
in the mobility of reactive Cu ions was elucidated via a combination
of density functional theory calculations, in situ impedance spectroscopy, and in situ diffuse reflectance
ultraviolet–visible spectroscopy. When the number of framework
Al sites decreases, the Brønsted acid sites decrease, leading
to a systematic increase in the diffusion barrier for [CuÂ(NH3)2]+ and less formation of highly reactive
dimer-Cu species, which inhibits the low-temperature NH3-SCR reactivity and vice versa. When the spatial distribution of
Al sites is uneven, the [CuÂ(NH3)2]+ complexes tend to migrate from an Al-poor cage to an Al-rich cage
(e.g., cage with paired Al sites), which effectively accelerates the
formation of dimer-Cu species and hence promotes the SCR reaction.
These findings unveil the mechanism by which framework Brønsted
acid sites influence the intercage diffusion and reactivity of [CuÂ(NH3)2]+ complexes in Cu-SSZ-13 catalysts
and provide new insights for the development of zeolite-based catalysts
with excellent SCR activity by regulating the microscopic spatial
distribution of framework Brønsted acid sites