Quantum chemical calculation of infrared spectra of acidic groups in chabazite in the presence of water

Mihaleva, VV; Santen, van Ra Rutger; Jansen, Apj Tonek

doi:10.1063/1.1709896

Cited by 23 publications

(51 citation statements)

References 38 publications

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“…Due to hydrogen bonding with the adsorbed H 2 O molecule the zeolitic OH stretching is strongly red-shifted, and resonance with the overtone of the in-plane SiOH bending creates a window at the overtone position (see Ref. [36] for a recent model calculation). Figure 22.4 shows the observed spectrum [37] and the assignment based on MP2 frequency calculations [34].…”

Section: Water Molecules and Clusters In Zeolitesmentioning

confidence: 99%

Proton Transfer in Zeolites

Sauer

2006

Hydrogen‐Transfer Reactions

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Section: Water Molecules and Clusters In Zeolitesmentioning

confidence: 99%

Proton Transfer in Zeolites

Sauer

2006

Hydrogen‐Transfer Reactions

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“…66 They can be attributed to the formation of strongly hydrogen bonded H + (H 2 O) n species or complexes of water with newly formed Brønsted acidic hydroxyl groups upon nitric acid adsorption. [72][73][74] The signature for hydrogen bonding is evidenced by the two broad absorption bands at ~ 2900 and ~ 2450 cm -1 . [72][73][74] A third broad absorption band at ~ 1700 cm -1 is more difficult to see in Figure 3.1 because of other absorption bands in this region.…”

Section: Hno3 Adsorption In Nay Zeolitementioning

confidence: 99%

“…[72][73][74] The signature for hydrogen bonding is evidenced by the two broad absorption bands at ~ 2900 and ~ 2450 cm -1 . [72][73][74] A third broad absorption band at ~ 1700 cm -1 is more difficult to see in Figure 3.1 because of other absorption bands in this region. [72][73][74] These three broad absorption bands have been proposed to be characteristic of hydrogen bonded hydroxyls arise due to a Fermi resonance of zeolite OH stretch mode with the overtone of bending vibrations.…”

Section: Hno3 Adsorption In Nay Zeolitementioning

confidence: 99%

“…[72][73][74] A third broad absorption band at ~ 1700 cm -1 is more difficult to see in Figure 3.1 because of other absorption bands in this region. [72][73][74] These three broad absorption bands have been proposed to be characteristic of hydrogen bonded hydroxyls arise due to a Fermi resonance of zeolite OH stretch mode with the overtone of bending vibrations. 74 Zeo − O − … Na + + HNO 3 ↔ Zeo − O − … H + + Na + NO 3 − (3.1)…”

Section: Hno3 Adsorption In Nay Zeolitementioning

confidence: 99%

“…[72][73][74] These three broad absorption bands have been proposed to be characteristic of hydrogen bonded hydroxyls arise due to a Fermi resonance of zeolite OH stretch mode with the overtone of bending vibrations. 74 Zeo − O − … Na + + HNO 3 ↔ Zeo − O − … H + + Na + NO 3 − (3.1)…”

Section: Hno3 Adsorption In Nay Zeolitementioning

confidence: 99%

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Heterogeneous and multiphase chemistry of trace atmospheric gases with mineral dust and other metal containing particles

Gankanda¹

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In this study, we investigated the effect of relative humidity on the oxidation of cyclohexane by photogenerated •OH radicals on TiO2 surface. At zero relative humidity (RH), only surface adsorbed oxidation products are present. In the presence of gas phase water vapor at higher relative humidities, gas phase cyclohexanone was also detected as an oxidation product. This gas phase cyclohexanone concentration was increased with increasing RH until 40%. This gas phase cyclohexanone product is absent at 73% RH. There are two possible sources of gas phase cyclohexanone; a) reaction of •OH radicals diffused into the gas phase with cyclohexane molecules b) diffusion of cyclohexanone molecules formed on the TiO2 surface to the gas phase. Absence of any gas phase products at 73% RH is probably due to limitations in the diffusion of •OH radicals or cyclohexanone product formed on the surface to the gas phase due to thicker adsorbed water layer.

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Experimental and theoretical IR study of methanol and ethanol conversion over H-SAPO-34

Hemelsoet

Ghysels

et al. 2011

Catalysis Today

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Theoretical and experimental IR data are combined to gain insight into the methanol and ethanol conversion over an acidic H-SAPO-34 catalyst. The theoretical simulations use a large finite cluster and the initial physisorption energy of both alcohols is calculated.Dispersive contributions turn out to be vital and the final adsorption of ethanol is predicted to be stronger compared to methanol (difference of 14 kJ mol −1 ). Calculated IR spectra of the alcohols and of formed aromatic cations upon conversion are also analyzed and support the peak assignment of the experimental in situ DRIFT spectra, in particular for the C-H and C=C regions. Theoretical IR spectra of the gas phase compounds are compared with those of the molecules loaded in a SAPO cluster and the observed shifts of the peak positions are discussed. To get a better understanding of these framework-guest interactions, a new theoretical procedure is proposed based on a normal mode analysis.A cumulative overlap function is defined and enables the characterization of individual peaks as well as induced frequency shifts upon adsorption.

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Quantum chemical calculation of infrared spectra of acidic groups in chabazite in the presence of water

Cited by 23 publications

References 38 publications

Proton Transfer in Zeolites

Proton Transfer in Zeolites

Heterogeneous and multiphase chemistry of trace atmospheric gases with mineral dust and other metal containing particles

Experimental and theoretical IR study of methanol and ethanol conversion over H-SAPO-34

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