Cu-CHA is the state-of-the-art catalyst for the Selective Catalytic Reduction (SCR) of NOx in vehicle applications.Although extensively studied, diverse mechanistic proposals still stand in terms of the nature of active Cu-ions and reaction pathwaysinSCR working conditions.Herein we address the redoxm echanism underlying Low-Temperature (LT) SCR on Cu-CHA by an integration of chemical-trapping techniques,transient-response methods,operando UV/Vis-NIR spectroscopyw ith modelling tools based on transient kinetic analysis and density functional theory calculations.W es how that the rates of the Reduction Half-Cycle (RHC) of LT-SCR displayaquadratic dependence on Cu II ,t hus questioning mechanisms based on isolated Cu II-ions.W ep ropose,i nstead, aCu II-pair mediated LT-RHC pathway,inwhichNOoxidative activation to mobile nitrite-precursor intermediates accounts for Cu II reduction. These results highlight the role of dinuclear Cu complexes not only in the oxidation part of LT-SCR, but also in the RHC reaction cascade.
We
combine gas phase Transient Response Methods with Transient
Kinetic Analysis to investigate the reduction half-cycle (RHC: CuII → CuI) of the Standard SCR redox mechanism
over Cu-CHA (chabazite) catalysts. The results confirm that NO + NH3 can readily reduce CuII at low temperatures (150–220
°C) according to a Cu:NO:NH3:N2 = 1:1:1:1
stoichiometry. The observed CuII reduction dynamics are
invariant with the CuII speciation. Unexpectedly, the CuII reduction rates show a quadratic dependence on CuII, which is hardly compatible with the so far proposed single-site
RHC mechanisms. The second order kinetics are found to apply under
both dry and wet conditions (0% and 2% H2O v/v in the feed
gas, respectively) across different temperatures, space velocities,
and NO feed concentrations over two powdered Cu-CHA catalysts with
different Cu loadings as well as over a commercial Cu-CHA washcoated
honeycomb monolith catalyst. Another unprecedented finding is that
H2O significantly inhibits the CuII reduction
rate and lowers the RHC apparent activation energy. These findings
provide for the first time a complete kinetic description of the low-temperature
RHC reaction cascade and, from a mechanistic perspective, strongly
suggest a dinuclear-CuII mediated RHC pathway, which may
renew interrogations on the current mechanistic understanding of the
CuII reduction pathway in the low-temperature NH3-SCR redox chemistry over Cu-CHA.
As the state-of-the-art
catalyst for the selective catalytic reduction
(SCR) of NOx, Cu-CHA has been extensively investigated
in both its practical and fundamental aspects. Among the latter, how
Z2Cu2+, an active site for SCR, participates
in low-temperature (LT) SCR reactions remains debated. Here, we propose
a scheme involving the hydrolysis of Z2Cu2+ to
ZCu2+(OH)−, a thermodynamically and kinetically
favorable process under LT-SCR conditions, based on multiple pieces
of evidence from a probe reaction (transient CO oxidation), transient
Cu2+ reduction kinetic runs, in situ FTIR spectroscopy,
and first-principles calculations. Such an integrated investigation
reveals unambiguously that the hydrolysis of Z2Cu2+ to ZCu2+(OH)− occurs facilely in the
presence of NH3, which may thus reconcile the identical
quadratic kinetics of Z2Cu2+/ZCu2+(OH)− reduction with the inactivity of Z2Cu2+ in the formation of Cu2+ pairs. Accordingly,
we highlight that NH3-assisted hydrolysis plays a critical
role in LT-SCR and should be taken into account especially when discussing
SCR reaction details over Z2Cu2+.
As
the state-of-the-art catalyst for the selective catalytic reduction
(SCR) of NOx from lean-burn engines, Cu-exchanged chabazite zeolite
(Cu-CHA) has been a spotlight in environmental catalysis because of
its preeminence in DeNOx performance and hydrothermal stability. The
microscopic cycling of active Cu cations between CuII and
CuI in response to dynamic, macroscopic reaction conditions
dominates SCR catalysis over Cu-CHA zeolites. In such cycling, Cu
cations are solvated by gas-phase reactants, e.g., NH3,
under low-temperature (LT) conditions, conferring peculiar mobility
to Cu-NH3 complexes and making them act as mobilized entities
during LT-SCR turnovers. Such motions provide LT-SCRa typical
heterogeneous catalytic processwith homogeneous features over
Cu-CHA, but, differently from conventional homogeneous catalysis,
the motions are tethered by electrostatic interactions between Cu
cations and conjugate Al centers. These features affect distinctly
the LT-SCR redox chemistry on Cu-CHA, resulting in, for example, the
involvement of two CuI-diamines in activating O2 and reoxidizing CuI to CuII (oxidation half-cycle,
OHC). The kinetically relevant reduction half-cycle (RHC) that reduces
CuII to CuI is far less understood particularly
within the context of such linked homo- and heterogeneous catalysis.
Here, we focus on the LT-RHC chemistry over Cu-CHA and summarize observations
from a series of recent, dedicated works from our group, benchmarking
these findings against those closely relevant in the literature. We
thus attempt to reconcile and rationalize results informed from independent,
multitechnique evidence and to further progress mechanistic insights
into LT-SCR catalysis, especially in the context of dynamic interconversion
between mono- and binuclear Cu sites.
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