Synthesis and Characterization of Mononuclear and Binuclear Copper Species in Cu-Exchanged Zeolites for Redox Reactions including Partial Methane Oxidation

Laura Wilcox (7534151)

13 October 2021

<p>Cu-zeolites have received renewed attention as catalytic materials that facilitate partial methane oxidation (PMO) to methanol, with a variety of mononuclear, binuclear, and multinuclear Cu active site motifs that have been proposed in prior literature. Our approach to more precisely identify and probe the Cu structures that activate O₂ and reduce in CH₄relies on the synthesis of model supports with varying composition and well-defined Cu speciation, which also facilitates connections between experimental data and theoretical models. Chabazite (CHA) zeolites are high-symmetry frameworks that contain a single lattice tetrahedral site (T-site), in which Cu²⁺ ions exchange at paired Al sites in a six-membered ring (6-MR) while CuOH⁺ species exchange at isolated 6-MR Al sites, the latter of which can react to form binuclear O/O₂-bridged Cu structures. In this work, Cu-CHA zeolites were synthesized to contain predominantly Cu²⁺ (Z₂Cu) or CuOH⁺ (ZCuOH) species of varying density, or a mixture of Z₂Cu and ZCuOH sites. Z₂Cu and ZCuOH sites were quantified by titration of residual Brønsted acid sites with NH₃, which respectively exchange with 2:1 or 1:1 H⁺:Cu²⁺ stoichiometry. Stoichiometric PMO reaction cycles on Cu-zeolites involved high-temperature (723 K) activation in O₂, and then moderate-temperature (473 K) reduction in CH₄ and treatment in H₂O (473 K) to extract CH₃OH. <i>I</i><i>n-situ</i> UV-Visible spectroscopy under oxidizing (O₂, 723 K) and reducing (CO, 523 K; CH₄, 473 K; He, 723 K) conditions detected the presence of mononuclear and binuclear Cu site types, while <i>in-situ</i> Cu K-edge X-ray absorption spectroscopy after such treatments was used to quantify Cu(I) and Cu(II) contents and <i>in situ</i> Raman spectroscopy was used to identify the Cu structures formed. ZCuOH, but not Z₂Cu sites, are precursors to binuclear O/O₂-bridged Cu sites that form upon O₂ activation and subsequently produce methanol after stoichiometric PMO cycles, at yields (per total Cu) that increased systematically with ZCuOH site density. The fraction of Cu(II) sites that undergo auto-reduction in inert at high temperatures (He, 723 K) is identical, within experimental error, to the fraction that reduces in CH₄ at temperatures relevant for PMO (473 K), providing a quantitative link between the binuclear Cu site motifs involved in both reaction pathways and motivating refinement of currently postulated PMO reaction mechanisms. These Cu-CHA zeolites were also studied for other redox chemistries including the selective catalytic reduction (SCR) of NO_x with NH₃. <i>In situ </i>UV-Visible and X-ray absorption spectroscopies were used to monitor and quantify the transient partial reduction of Cu(II) to Cu(I) during exposure to NH₃ (473 K), in concert with titration methods that use NO and NH₃ co-reductants to fully reduce all Cu(II) ions that remain after treatment in NH₃ alone to the Cu(I) state, providing quantitative evidence that both Z₂Cu and ZCuOH sites are able to reduce in NH₃ alone to similar extents as a function of time. These findings provide new insight into the reaction pathways and mechanisms in which NH₃ behaves as a reductant of mononuclear Cu(II) sites in zeolites, which are undesired side-reactions that occur during steady-state NO_x SCR and that often unintendedly result in Cu(II) reduction prior to spectroscopic or titrimetric characterization. Overall, the strategy in this dissertation employs synthetic methods to control framework Al density and arrangement in zeolite supports to emphasize extra-framework Cu site motifs of different structure and at different spatial densities, and to interrogate these model materials using a combination of <i>in situ</i> spectroscopic techniques together with theory, in order to elucidate active site structure and proximity requirements in redox catalysis. This work demonstrates how quantitative reactivity and site titration data, brought together with an arsenal of tools available in contemporary catalysis research, can provide detailed mechanistic insights into transition metal-catalyzed redox cycles on heterogeneous catalysts.</p>

in situ characterization

redox chemistry

partial methane oxidation

Binuclear active sites

Cu-CHA zeolites

<b>INFLUENCE OF CHABAZITE ZEOLITE MATERIAL PROPERTIES ON METAL-OXO ACTIVE SITE DISTRIBUTIONS FOR PARTIAL METHANE OXIDATION</b>

Andrew D Mikes (18116080)

07 March 2024

<p dir="ltr">Partial methane oxidation (PMO) to methanol is a desirable route for upgrading natural and shale gas resources to liquid chemical intermediates and has been extensively studied on Cu-zeolites. Prior work has studied the stoichiometric PMO reaction on O₂-activated Cu-zeolites, leading to several proposals for candidate O_x-bridged Cu active site structures. More recent studies have investigated the catalytic PMO reaction and have reported that Cu-chabazite (CHA) zeolites tend to exhibit the highest methane oxidation rate (per Cu) among other Cu-zeolite topologies. Multiple studies have reported that decreasing the Cu site density and increasing the framework Al density increase the selectivity towards methanol, but have proposed different mechanistic explanations. Here, we study the influence of Cu active site distribution, which was altered by varying the extraframework Cu site density and the arrangement of framework Al atoms, on the kinetic parameters governing continuous PMO. The number of redox active Cu species was quantified through linear combination fitting of XANES spectra collected under <i>in situ</i> and transient conditions after reactant (O₂) cut-off, and the Cu speciation was investigated with XAS. Total methane oxidation rates and individual product formation rates (CH₃OH, CO, CO₂), normalized per total Cu, increased with Cu density because this influenced the speciation of Cu formed during the reaction. All Cu-CHA samples showed PMO rates that were nearly first-order in CH₄ pressure, consistent with prior reports that C-H activation in CH₄ is the rate limiting step. Samples with differing framework Al arrangement, but fixed extraframework Cu density, showed formation rates of over-oxidation products (e.g., CO₂) that had different apparent reaction orders in O₂, implying differences in the Cu active sites formed during reaction. Changes to Cu oxidation states were monitored with <i>in situ</i> XAS. Samples were first subjected to an oxidative pretreatment (723 K, 5 kPa O₂) and then to catalytic PMO conditions to reach steady-state. Steady-state XANES spectra collected after O₂ was removed from the reactant stream showed the expected reduction from Cu(II) to Cu(I), and the fraction of CH₄-reducible Cu(II) sites decreased with increasing Cu content; increasing the CH₄ pressure ten-fold increased the number of CH₄-reducible sites by a factor of ~1.5. These spectroscopic and kinetic observations suggest there are a mixture of Cu site types that are present during catalysis, each with different intrinsic reactivity toward CH₄ and selectivity to CH₃OH. To rationalize these observations, a reaction mechanism is proposed for a two-site model and used to derive rate expressions that describe apparent reaction orders for the total CH₄ oxidation rate and product formation rates on Cu-CHA zeolites of varying Cu content.</p><p dir="ltr">Additional routes for CH₄ activation include partial CH₄ oxidation over Fe zeolites that convert CH₄ at ambient temperature following an activation in nitrous oxide (N₂O), or through CH₄ dehydroaromatization (DHA) to benzene over Mo zeolites under non-oxidative conditions. Prior work on PMO over Fe-zeolites has identified candidate active site structures, but the influence of zeolite structural properties on ion-exchanged Fe speciation remains unclear. This work sought to understand the interaction of Fe with the zeolite framework during solvent-assisted deposition procedures and subsequent thermal treatments. In pursuit of this objective, Fe uptake isotherms were measured, and Fe speciation was characterized with UV-Vis spectroscopy and H₂ temperature programmed reduction (H₂ TPR). Increased framework Al site pairing increased the uptake of Fe in CHA zeolites, and high temperature treatments (723 K) resulted in the formation of oligomeric Fe structures as indicated by UV-vis. In CH₄ DHA over Mo-MFI, a principal challenge is the irreversible loss of catalytic reactivity with repeated reaction-regeneration cycles, attributed to dealumination of the zeolite structure during high-temperature oxidative regeneration treatments that produce steam. CHA zeolites are known to be more resistant to dealumination than MFI, but its smaller pore structure prevents diffusion of benzene and other aromatic products leading to rapid coking. This work attempted to address the diffusion limitations for benzene in Mo-CHA by synthesizing crystals with nanoscale dimensions by incorporating a surfactant into the crystallization procedure, generating solids with a flake-like morphology.</p><p dir="ltr">The overarching strategy in this work was to influence the speciation of metal sites and complexes in zeolites by controlling the density and arrangement of anionic Al anchoring sites within the framework and the density of extraframework metal species. In the case of Cu-zeolites, the amount of Cu present on the material influences the structures that form during catalysis that influences both the rate and selectivity of catalytic PMO.</p>

Heterogeneous Catalysis Kinetics

Copper

Zeolites

Partial Methane Oxidation

Spectroscopy

Reaction Mechanisms

Active Sites

Binuclear active sites