The Mechanism of Methanol to Hydrocarbon Catalysis

Haw, James F.; Song, Weiguo; Marcus, David M.; Nicholas, John B.

doi:10.1021/ar020006o

“…Figure 4 depicts the induction periods (black) and active periods (red) of catalysts deactivated by the three different methanol purities as measured by on‐line mass spectrometry. Feedstock impurities clearly have an effect on the induction period as previously reported 40, 61, 62, 63, 64. The results summarized in Figure 4 show that methanol feedstock (U), containing very few impurities, has the longest induction and active periods.…”

Section: Resultssupporting

confidence: 75%

Effect of Feedstock and Catalyst Impurities on the Methanol‐to‐Olefin Reaction over H‐SAPO‐34

Vogt

¹

,

Weckhuysen

²

,

Ruiz‐Martínez

³

2016

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Operando UV/Vis spectroscopy with on‐line mass spectrometry was used to study the effect of different types of impurities on the hydrocarbon pool species and the activity of H‐SAPO‐34 as a methanol‐to‐olefins (MTO) catalyst. Successive reaction cycles with different purity feedstocks were studied, with an intermittent regeneration step. The combined study of two distinct impurity types (i.e., feed and internal impurities) leads to new insights into MTO catalyst activation and deactivation mechanisms. In the presence of low amounts of feed impurities, the induction and active periods of the process are prolonged. Feed impurities are thus beneficial in the formation of the initial hydrocarbon pool, but also aid in the unwanted formation of deactivating coke species by a separate, competing mechanism favoring coke species over olefins. Further, feedstock impurities strongly influence the location of coke deposits, and thus influence the deactivation mechanism, whereas a study of the organic impurities retained after calcination reveals that these species are less relevant for catalyst activity and function as “seeds” for coke formation only.

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“…2b, c). Our simulation well supports the real experimental observations that higher pressure and a lower temperature may benefit the yield of aromatics [2,11,17,18].…”

Section: Computer-aided Simulations For Three Reactions Of Different supporting

confidence: 86%

“…Like other researches, in our experiments methanol conversion mainly yield large portion of gas alkanes, gas olefins, as well as aromatics [4,5,11]. This is owing to the continuous flow of methanol feedstock and the non-stop transportation of previous formed products to the outside of the system (before the catalyst deactivates); in other words, the reaction happens in an opening system, which greatly reduces the chances of coke formation.…”

Section: Introductionsupporting

confidence: 63%

“…Although the MTH mechanism is in a great complexity, thermodynamics are not affected by the reaction routes. The selected 25 reactions have covered all the directions from methanol to the major MTH products (C 1 -C 9 ) with essential product intra-conversions, and are supposed to happen in a real MTH system proceeding in timeon-stream [11,12]. Particularly, we have further separated the isomers of xylene and tri-methylbenzene, for a more comprehensive study than the previous works, and a consideration that para-xylene might be the most favourable product in the methanol to aromatics process via H-ZSM-5 zeolite [4,8,9].…”

Section: Initial Work-thermodynamic Calculations On Selected Sub Reacmentioning

confidence: 99%

“…However, our assumption is based on the 'hydrocarbon-pool' cycle, which has been considered as the origin of series of MTH reactions and gives C 2 -C 4 olefins and methyl-aromatics as the primary products [4]. Further consideration is given to the fact that latter stage hydrogen transfer may convert these primary products into either saturated hydrocarbons (alkanes) or graphite species (deeply dehydrogenated cokes), and these intra-conversions indeed play an important role in deciding the following catalytic process, and the final product yields [3,4,11,12]. This simulation also takes the advantage that all of these 'hydrocarbon-pool' primary products (C 2 -C 4 olefins and C 6 -C 9 aromatics) take a large portion in the product yield of short time (a few minutes to several hours) lab reactions and industrial applications [4,5].…”

Section: Computer-aided Simulations For Three Reactions Of Different mentioning

confidence: 99%

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A research into the thermodynamics of methanol to hydrocarbon (MTH): conflictions between simulated product distribution and experimental results

Liu

¹

,

Yao

²

,

González-Cortés

³

et al. 2017

Appl Petrochem Res

3

0

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Thermodynamic calculations and analysis were carried out for a rational understanding of the results from selected laboratory MTH reactions. Simulations without solid carbons (coke), CO, CO 2 and light alkanes target on the yield of olefin and aromatic products, which has been found better referenced to the real experimental observations that occur in time-on-stream (TOS). The confliction between simulated data and real experimental results is presumably ascribed to the limited dwelling time of products in the reaction system. Hydrocarbon pool based reactions donate olefins and methyl-benzenes as primary products in a continuous-flow MTH reaction; when the dwelling time of product extends intra-conversions (H 2 transfers) between products would further adjust the composition of MTH yield, in which case alkanes and aromatic products (cokes precursors) increase. In the case of intraconversions are ignored due to limited product dwelling time, thermodynamic calculation on Gibbs free energy change of selected sub reactions shows fairly close results to the real experimental data, which well supports the above explanations. This work highlights the importance of proper choosing target products and/or sub reactions for a rational thermodynamic prediction of MTH product distribution obtained in time-on-stream.Keywords Methanol to hydrocarbon Á Hydrocarbon pool mechanism Á Thermodynamic Á Intra-conversion Á Dwelling time IntroductionAt present, the pathways of methanol to hydrocarbon reaction especially the formation of first C-C bond are still in debate. The most acceptable hypothesis by far relies on the mechanism based on a 'hydrocarbon pool' [1]. In this theory, limited trace amount of hydrocarbons introduced as impurities in the methanol feedstock formed the initial aromatics (some benzene ring structures), which play a key role as the 'scaffold' in later process [2]. Methyl groups are added onto the hydrocarbon pool molecules in alkylation steps and light olefins are subsequently formed by the corresponding de-alkylation steps. The initial olefins can be converted into alkanes by occupying H 2 , whereas continuous loss of H 2 , followed by the cyclization steps forms more aromatics [3][4][5]. In a mature MTH system, series of the above reactions proceed in a parallel way and, therefore, bring in a complexity to the products and orders of their formation; however, thermodynamics always say coke (extremely dehydrogenated products, or solid carbons) is the dominating product in MTH and most other hydrocarbon transformations [6]. Before the reaction reaches a final format of solid carbons [C (s) ], Electronic supplementary material The online version of this article

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Zeolites

Broach¹,

Jan²,

Lesch³

et al. 2012

Ullmann's Encyclopedia of Industrial Chemistry

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The article contains sections titled: 1. Introduction 2. Nomenclature 3. History 4. Structure, Composition, and Properties 4.1. Framework Structure 4.2. Nonframework Cations 4.3. Chemical and Physical Properties 4.3.1. Physical Properties 4.3.2. Chemical Properties 5. Characterization 6. Occurrence, Mining, and Processing of Natural Zeolites 7. Production of Synthetic Zeolites 7.1. Chemistry of Zeolite Synthesis 7.2. Composition of Reaction Mixtures 7.3. Raw Materials 7.3.1. Synthesis Conditions 7.3.2. Examples of Industrial Zeolite Syntheses 7.3.3. Post Synthesis Treatments 7.3.4. Environmental Aspects 8. Commercial Applications and Importance 8.1. Natural Zeolites 8.2. Synthetic Zeolites 8.2.1. Adsorption 8.2.2. Membranes 8.2.3. Catalysis 8.2.4. Other Uses 9. Toxicology Zeolites are hydrated aluminosilicates with a three‐dimensional framework structure constructed of SiO 4 and AlO 4 tetrahedra linked through oxygen atoms. They contain regular channels or interlinked voids whose aperture diameters are in the micropore range. The regular nature of the channels and apertures, whose dimensions are of the same order of magnitude as molecular diameters, enables the zeolites to function as molecular sieves and gives them value as selective adsorbents for separating substances and as shape‐selective catalysts. This article gives an overview of history, structure, properties, occurrence, production, and applications of zeolites.

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The Mechanism of Methanol to Hydrocarbon Catalysis

Cited by 894 publications

References 40 publications

Effect of Feedstock and Catalyst Impurities on the Methanol‐to‐Olefin Reaction over H‐SAPO‐34

Effect of Feedstock and Catalyst Impurities on the Methanol‐to‐Olefin Reaction over H‐SAPO‐34

A research into the thermodynamics of methanol to hydrocarbon (MTH): conflictions between simulated product distribution and experimental results

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