Catalysis on solid acids: Mechanism and catalyst descriptors in oligomerization reactions of light alkenes

Sarazen, Michele L.; Doskocil, Eric J.; Iglesia, Enrique

doi:10.1016/j.jcat.2016.10.010

Cited by 85 publications

(117 citation statements)

References 63 publications

(85 reference statements)

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“…(49)]. These data suggest that more stable anions (in stronger acids) do not lead to more stable alkoxides, an experimental demonstration of the covalent nature of the alkoxide structures, which is consistent with DFT-derived formation energies and partial charges for s-propoxides that are independent of acid strength for a series of Keggin POM clusters with different central atoms and very different acid strength (HPW, HSiW, HAlW) (12). These data also show that stabilization by confinement is similar among different alkoxides and not very consequential for their stability within 12-MR MOR channels, but becomes detectable within smaller 10-MR TON channels.…”

Section: Resultssupporting

confidence: 69%

“…from NH 4 + decomposition (6)] are proportional to the alkene pressure (10-500 kPa; 503 K) (Fig. 1A), consistent with the kinetic relevance of the alkene-alkoxide reactions that form the C-C bond (12). At lower propene pressures (1-5 kPa), dimerization rates deviate from first order (Fig.…”

Section: Experimental Methodssupporting

confidence: 67%

“…Infrared spectra also show that O-H stretching bands [3,600 cm , the frequency range expected from theoretical treatments for π-bonded alkenes at protons (7,12). Thus, bound species predominantly consist of covalently bound alkoxides.…”

Section: Resultsmentioning

confidence: 84%

“…This uncertainty is particularly prevalent in isobutene-derived species, for which steric effects may disfavor the formation of covalently bound butoxides (7)(8)(9). Infrared spectra that lack intact or perturbed O-H stretches (10,11) during oligomerization of propene or isobutene on TON and MFI (12) indicate the proton has been transferred to the stable species, which is consistent for either the covalently bound alkoxide or carbenium ion. However, density functional theory (DFT) shows that alkoxides acquire carbenium ion character only at the transition states that mediate their transformations during catalysis on solid acids, but not at their lowest energy stable bound states (13)(14)(15)(16)(17)(18)(19), which suggests the prevalence of bound alkoxides at near saturation coverages during catalysis.…”

mentioning

confidence: 99%

“…We combine here these methods to report the thermodynamics of alkoxides derived from C 2 -C 4 alkenes during their co-oligomerization on acids of diverse strength and confining environments (H-TON [10-membered ring (MR)] zeolite; H-MOR (12-MR) zeolite; Keggin polyoxometalates dispersed on mesoporous SiO 2 (H 3 PW 12 O 40 ; HPW)). Theory (DFT) and experiment show that C-C bond formation rates are limited by the addition of an alkene to bound alkoxides, present at saturation coverages at all alkene pressures (10-500 kPa) (12). At lower pressures, absolute alkoxide formation equilibrium constants for ethoxide and propoxides are measured from homodimerization rates and from the integration of infrared bands that are dependent on alkene pressure; their relative values agree with DFT-derived adsorption free energies and values measured from heterodimerization where competition for surface sites exists.…”

mentioning

confidence: 99%

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Stability of bound species during alkene reactions on solid acids

Sarazen

Iglesia

2017

Proc. Natl. Acad. Sci. U.S.A.

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This study reports the thermodynamics of bound species derived from ethene, propene, n-butene, and isobutene on solid acids with diverse strength and confining voids. Density functional theory (DFT) and kinetic data indicate that covalently bound alkoxides form C-C bonds in the kinetically relevant step for dimerization turnovers on protons within TON (0.57 nm) and MOR (0.67 nm) zeolitic channels and on stronger acids HPW (polyoxometalate clusters on silica). Turnover rates for mixed alkenes give relative alkoxide stabilities; the respective adsorption constants are obtained from in situ infrared spectra. Tertiary alkoxides (from isobutene) within larger voids (MOR, HPW) are more stable than less substituted isomers but are destabilized within smaller concave environments (TON) because framework distortions are required to avoid steric repulsion. Adsorption constants are similar on MOR and HPW for each alkoxide, indicating that binding is insensitive to acid strength for covalently bound species. DFT-derived formation free energies for alkoxides with different framework attachments and backbone length/structure agree with measurements when dispersion forces, which mediate stabilization by confinement in host-guest systems, are considered. Theory reveals previously unrecognized framework distortions that balance the C-O bond lengths required for covalency with host-guest distances that maximize van der Waals contacts. These distortions, reported here as changes in O-atom locations and dihedral angles, become stronger for larger, more substituted alkoxides. The thermodynamic properties reported here for alkoxides and acid hosts differing in size and conjugate-anion stability are benchmarked against DFT-derived free energies; their details are essential to design hostguest pairs that direct alkoxide species toward specific products.zeolites | alkene adsorption | heterogeneous catalysis | density functional theory H ydrocarbon reactions on solid Brønsted acids often involve bound alkene-derived intermediates. Their reactivity and selectivity in C-C bond formation and cleavage and in hydrogen transfer reactions depend on their thermodynamic properties, which reflect, in turn, the properties of the conjugate anion and of the confining voids in microporous solid acids. Weakly bound adsorbed alkanes interact with void walls via dispersion forces at low temperatures without molecular transformations; their unreactive nature allows accurate assessments of their binding properties (1-4). Alkenes interact with protons via H bonding or π-interactions, as well as by proton transfer from strong acids to form alkoxides; the intermediate between these states is a positively charged carbenium ion. The thermodynamics of alkoxide formation remain uncertain because of their very fast oligomerization and β-scission reactions (5, 6), thus requiring indirect inferences from kinetic, spectroscopic, or theoretical methods. This uncertainty is particularly prevalent in isobutene-derived species, for which steric effects may disfavor the f...

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Section: Resultssupporting

confidence: 69%

Section: Experimental Methodssupporting

confidence: 67%

Section: Resultsmentioning

confidence: 84%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Stability of bound species during alkene reactions on solid acids

Sarazen

Iglesia

2017

Proc. Natl. Acad. Sci. U.S.A.

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Rigid Arrangements of Ionic Charge in Zeolite Frameworks Conferred by Specific Aluminum Distributions Preferentially Stabilize Alkanol Dehydration Transition States

et al. 2020

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Zeolite reactivity depends on the solvating environments of their micropores and the proximity of their Brønsted acid sites.T urnover rates (per H +)f or methanol and ethanol dehydration increase with the fraction of H + sites sharing sixmembered rings of chabazite (CHA) zeolites.D ensity functional theory (DFT) shows that activation barriers vary widely with the number and arrangement of Al (1-5 per 36 T-site unit cell), but cannot be described solely by Al-Al distance or density.C ertain Al distributions yield rigid arrangements of anionic charge that stabilizec ationic intermediates and transition states via H-bonding to decrease barriers.T his is ak ey feature of acid catalysis in zeolites olvents,w hichl ack the isotropyo fl iquid solvents.T he sensitivity of polar transition states to specific arrangements of charge in their solvating environments and the ability to position such charges in zeolite lattices with increasing precision herald rich catalytic diversity among zeolites of varying Al arrangement.

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