Catalytic Consequences of Protons in Methanol Oxidative Dehydrogenation on Molybdenum-Based Polyoxometalate Clusters

Cai, Guangming; Chin, Ya-Huei Cathy

doi:10.1021/acscatal.4c00440

ACS Catal.

2024

DOI: 10.1021/acscatal.4c00440

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Catalytic Consequences of Protons in Methanol Oxidative Dehydrogenation on Molybdenum-Based Polyoxometalate Clusters

Guangming Cai,

Ya-Huei Cathy Chin

Abstract: This study unravels the catalytic effects of adjacent protons in redox catalysis of bifunctional Keggin-type phosphomolybdic acid clusters (H3PMo12O40). Isolated redox sites (O) and Brønsted acid-redox site pairs (OH/O) catalyze methanol oxidative dehydrogenation (ODH), a redox reaction, via the identical elementary steps and the formation of the kinetically relevant [HOCH2···H···O]‡ and [OH···HOCH2···H···O]‡ transition states, but with different kinetic requirements, established from selective site inacti… Show more

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Cited by 3 publications

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Mechanistic insights into methanol steam reforming on copper catalysts: Dynamics of active sites and reaction pathway

Liu,

Zhang,

Zhao

et al. 2025

Journal of Catalysis

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Mechanistic insights into methanol steam reforming on copper catalysts: Dynamics of active sites and reaction pathway

Liu,

Zhang,

Zhao

et al. 2025

Journal of Catalysis

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Cation Effects on the Brønsted Acidity of Solid Tungstosilicic Acid Clusters

Cai,

Deshlahra,

Chin

2024

ACS Catal.

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Rigorous kinetic assessments, pyridine chemical titration and desorption, together with density functional theory calculations establish the trends in the modulation of chemical identity, valence, site density, and strength of Brønsted acid sites by counter cations (Na + , K + , Cu 2+ , Mg 2+ , and Al 3+ ) on Keggin-type polyoxometalate tungstosilicic acid clusters (H 4 SiW 12 O 40 , POM). Monovalent cations (Na + and K + ) exchange protons and decrease the acid strength of the residual protons, as indicated by the deprotonation energy (DPE) that increases from 1100 to 1175 kJ mol −1 with an increasing extent of proton exchange (decreasing the nominal H + -to-POM ratio). In contrast, di-and trivalent cations preferentially exchange protons in the form of hydroxides (Y z+ (OH) m , Y z+ = Cu 2+ , Mg 2+ , or Al 3+ , 0 < m < z), resulting in an average DPE value on both POM clusters and associated hydroxides ranging between 1100 and 1150 kJ mol −1 . A portion of these cations disperse on the silica support, generating Lewis acid sites. The exchanged cations modulate the charge within the W 12 O 36 oxide shell, rather than the central SiO 4 4− tetrahedron, which mainly modifies the ionic component of DPE values. Monovalent cations with smaller electronegativities than di-and trivalent cations donate more electrons, which increases the electrostatic interaction of residual protons with conjugate POM − anions and leads to higher DPE values (weaker acids). This study expands the library of Brønsted acidic catalysts with flexibility in tuning their acid strengths and densities, thus providing a series of samples for constructing structure−reactivity relationships and probing site electrostatic correlations on structurally constrained domains.

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Thermochemical Correlations of Redox and Brønsted Sites on Bifunctional Polyoxometalate Clusters and Their Kinetic Consequences in Methanol-O₂ Catalysis

Cai,

Chin

2024

ACS Catal.

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Kinetic interconnectivities of methanol oxidative dehydrogenation and dehydration are manifestation of the underlying thermochemical/electronic correlations between redox and Brønsted sites on bifunctional Keggin-type polyoxometalate (POM) phosphomolybdic acid clusters with their electronic properties perturbed by sodium cation exchange (H x Na 3−x PMo, x = 3−0). As sodium exchange increases, activation free energies for the elementary C−H scission in methanol oxidative dehydrogenation, occurring at isolated redox sites (O*) or Brønsted acid-redox site pairs (OH/O*), and for the first-order C−O formation in methanol dehydration, occurring at Brønsted sites, increase proportionally within 10−11 kJ mol −1 at 433 K, while their activation enthalpies exhibit an inverse correlation. A Born−Haber thermochemical analysis reveals the reasons behind the site interconnectivities by establishing their respective kinetic-thermochemical relationships. The kinetically relevant C−H scission involves a late transition state, either [HOCH 2 •••H•••O*] ‡ at O* or [OH•••HOCH 2 •••H•••O*] ‡ at OH/O*, with the transfer of an electron (e − ) and a proton (H + ) as an H atom (H•) from the methyl fragment to redox sites, where hydrogen addition energy (HAE), comprising the negative electron affinity (−EA POM ) and proton affinity (−PA) of POM clusters, is a kinetic descriptor. The parallel methanol C−O formation features a late carbocationic transition state, [(CH 3 OH•••CH 3 + •••H 2 O)•••POM − ] ‡ , involving proton transfer from POM clusters to adsorbed methanol species, where the deprotonation energy (DPE) of the Brønsted site serves as a kinetic descriptor. Notably, hydrogen addition energy decreases by ∼23 kJ mol −1 , while deprotonation energy increases by 80−230 kJ mol −1 , as sodium exchange increases. This slight negative thermochemical correlation arises from the inherent opposing proton transfers during redox (−PA) and Brønsted acid catalysis (DPE), modulated by the energetic effect of electron transfer (−EA POM ) upon sodium exchange on H x Na 3−x PMo clusters (x = 3−1). The mechanistic interpretation and framework established here explicitly correlate the kinetic, thermochemical, and electronic properties of redox and Brønsted sites, offering insights into their intrinsic reactivity couplings, and are applicable to other bifunctional catalysts.

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Catalytic Consequences of Protons in Methanol Oxidative Dehydrogenation on Molybdenum-Based Polyoxometalate Clusters

Cited by 3 publications

References 58 publications

Mechanistic insights into methanol steam reforming on copper catalysts: Dynamics of active sites and reaction pathway

Mechanistic insights into methanol steam reforming on copper catalysts: Dynamics of active sites and reaction pathway

Cation Effects on the Brønsted Acidity of Solid Tungstosilicic Acid Clusters

Thermochemical Correlations of Redox and Brønsted Sites on Bifunctional Polyoxometalate Clusters and Their Kinetic Consequences in Methanol-O₂ Catalysis

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Catalytic Consequences of Protons in Methanol Oxidative Dehydrogenation on Molybdenum-Based Polyoxometalate Clusters

Cited by 3 publications

References 58 publications

Mechanistic insights into methanol steam reforming on copper catalysts: Dynamics of active sites and reaction pathway

Mechanistic insights into methanol steam reforming on copper catalysts: Dynamics of active sites and reaction pathway

Cation Effects on the Brønsted Acidity of Solid Tungstosilicic Acid Clusters

Thermochemical Correlations of Redox and Brønsted Sites on Bifunctional Polyoxometalate Clusters and Their Kinetic Consequences in Methanol-O2 Catalysis

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Thermochemical Correlations of Redox and Brønsted Sites on Bifunctional Polyoxometalate Clusters and Their Kinetic Consequences in Methanol-O₂ Catalysis