Catalytic Cracking of Heavy Aromatics and Polycyclic Aromatic Hydrocarbons over Fluidized Catalytic Cracking Catalysts

Pujro, Richard; Falco, Marisa; Sedrán, Ulises

doi:10.1021/ef502707w

Cited by 31 publications

(17 citation statements)

References 39 publications

(103 reference statements)

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“…In the Figure 3.b we are witness of increased peak of target compounds between sampling times of 1 min and 2 min in UV-C/TiO2 test and then decrease the DE peaks in following sampling times, could be explained by catalytic cracking of PAHs via HMW-PAHs to LMW-PAHs during the process (Pujro et al, 2015) HMW-PAHs include compounds with five and six fused aromatic rings which are strongly carcinogenic and mutagenic. Further, due to the number of benzene rings and unsaturation degree they become increasingly stable and nonbiodegradable (Stogiannidis and Laane, 2015).…”

Section: Uv-c Irradiated Treatmentsmentioning

confidence: 96%

“…According to the results, high performance of UV-C/H2O2, Xe, and Xe /H2O2 treatments was evidenced in degradation of Acy. The Acy decreased 6.94% at min 5 subsequently 100% after min 2 under Xe/TiO2 treatment, it could be explainable as catalytic cracking of PAHs by high molecular weight (HMW-PAHs) to lower molecular weight (LMW-PAHs) PAHs during the process too (Pujro et al, 2015).…”

Section: Uv-c Irradiated Treatmentsmentioning

confidence: 98%

“…The results suggest the high performance of Xe and Xe/H2O2 treatments in degradation of Nap. Observation of the increased peak of Nap at primary sampling times (1 and 2 min) of the Xe/TiO2 treatment and stay undegraded (just 40% degraded) up to end of treatment (Figure 4.b) could be explained as catalytic cracking of PAHs by high molecular weight (HMW-PAHs) to lower molecular weight (LMW-PAHs) PAHs during the process (Pujro et al, 2015).…”

Section: Uv-c Irradiated Treatmentsmentioning

confidence: 99%

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Abatement efficiency and fate of EPA-Listed PAHs in aqueous medium under simulated solar and UV-C irradiations, and combined process with TiO2 and H2O2

Kargar¹,

Amani‐Ghadim²,

Matin³

et al. 2020

EgeJFAS

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Photolytic degradation of dissolved compounds of 16 EPA-Listed PAHs in aqueous medium, exposed to ultraviolet/ titanium dioxide (UV-C/TiO2), xenon light/ titanium dioxide (Xe/TiO2), xenon light/ hydrogen peroxide (Xe/H2O2) and ultraviolet/ hydrogen peroxide (UV-C/H2O2) was studied. The compounds which detected above detection limit of applied analytical method and instrument include: naphthalene (Nap), acenaphthylene (Acy), acenaphthene (Ace), fluorene (Flu), fluoranthene (Fln) and pyrene (Pyr) survived. A time-course experiment (0, 1, 2, 5, 12 min) was performed to determine the fate of PAHs profile along treatments. After accomplishment of the removal process ∑6 PAHs ranked as follow: UV-C/TiO2 > Xe/TiO2 > UV-C > Xe > Xe/H2O2, and UV-C /H2O2 with estimated values of 76.38, 23.02, 22.55, 2.78, 0.00 and 0.00% of the concentration values at the beginning of the treatment, respectively. High efficiency of Xe/H2O2 treatment process (100.00%) at the end of treatment and the structure of residual PAHs which changed to the lighter compounds (2,3-ringed PAHs) before accomplishment of the removal process were proven. Generally, low resistance of Fln to all treatment conditions was observed. Total removal of Nap was considered to be a characteristic PAH compound for completion of the removal of PAHs. Mutate of parent PAH compounds and intermediates were analyzed by gas chromatography-mass spectrometry (GC-MS) and the results suggest the evaluating the toxicity of the treated water due to by-product formation concerns.

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Section: Uv-c Irradiated Treatmentsmentioning

confidence: 96%

Section: Uv-c Irradiated Treatmentsmentioning

confidence: 98%

Section: Uv-c Irradiated Treatmentsmentioning

confidence: 99%

See 1 more Smart Citation

Abatement efficiency and fate of EPA-Listed PAHs in aqueous medium under simulated solar and UV-C irradiations, and combined process with TiO2 and H2O2

Kargar¹,

Amani‐Ghadim²,

Matin³

et al. 2020

EgeJFAS

View full text Add to dashboard Cite

show abstract

“…The possible reactions during lubricant usage in the crankcase were thermal dehydrogenation, ring opening, epoxidation, cracking, and condensation of aromatics such as, phenyloctane, biphenyl, fluorene, 9,10-dihydrophenanthrene, naphthalene, phenanthrene, pyrene, and benzo(a)anthracene which are base oil components or additives in the lubricant formulation [39].…”

Section: C10h8 + 2o2 → C6h4(cho)2 + Ch3co2hmentioning

confidence: 99%

Potentials of African Star Apple (<i>Chrysophyllum albidum)</i> Fruit Shell Adsorbent in Recovery of Valuable Hydrocarbons for Spent Engine Oil

Taiwo

Tokede

Sanda

2021

IJET

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Inventory of spent engine oil continuously increase and indiscriminately disposed of at auto-mechanics garages. Adsorptive separation established to be indispensable in recovery of these hydrocarbons was carried out using Chrysophyllum albidum (African star apple) fruit shell – a renewable resource. In this study, clay pretreated spent engine oil was recovered in a fixed bed adsorption processes and the recovered adsorbate components determined by GC-MS analysis. The results showed African star apple fruit shell adsorbent effective in recovering n-hexane solubilized spent lubricating oil. The study concluded that using the developed African star apple fruit shell adsorbent, an agricultural waste adsorbent in the recovery of waste lubricating oil will enhance greatly the nation’s economy.

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“…Conversions of heavy hydrocarbon resources into value‐added chemicals are becoming more and more important, since heavier crude oil with high mining cost has been more supplied . Monoaromatic hydrocarbons with a long side chain are included in products of catalytic cracking of polycyclic aromatic hydrocarbons which are one class of main components of heavy oil . Except ethylbenzene, monoaromatic hydrocarbons with long alkyl chains are not so useful chemicals and are mainly used as fuel.…”

Section: Introductionmentioning

confidence: 99%

Selective C−C Hydrogenolysis of Alkylbenzenes to Methylbenzenes with Suppression of Ring Hydrogenation

et al. 2018

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Selective reduction of alkylbenzenes, which are supplied by refining heavy hydrocarbons, to methylbenzenes by selective CÀC hydrogenolysis was accomplished by Ru/CeO 2 catalyst. Hydrogenolysis of ethylbenzene was carried out with gas-phase fixed-bed flow reactor and various noble metal catalysts. The catalyst with high Ru loading (4 wt%) on CeO 2 support precalcined at high temperature (1073 K; Ru(4)/CeO 2 1073 catalyst) showed both good activity and selectivity to toluene. The yield of toluene reached 65 %-C in the conditions of 533 K and H 2 partial pressure of 0.075 MPa. Hydrogenolysis of other alkylbenzenes including p-ethyltoluene, propylbenzene and cumene was also carried out. Hydrogenolysis of C aryl -C alkyl bond and hydrogenation of benzene ring was slow in all substrate cases. Hydrogenolysis of p-ethyltoluene can give p-xylene as the main product (highest yield: 53 %-C). These high yields of methylbenzenes make a marked contrast to the traditional bifunctional hydrocracking systems which preferably dissociate C aryl -C alkyl bond in alkylbenzenes. Characterization of Ru catalysts suggests that the block-shaped Ru particles with small size (< 2 nm) in Ru(4)/CeO 2 1073 give good catalytic performance. Too strong interaction between Ru species and CeO 2 support induced by decreasing the loading amount rather gives ring-hydrogenation activity and decreases methylbenzenes selectivity.[a] S.

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Catalytic Cracking of Heavy Aromatics and Polycyclic Aromatic Hydrocarbons over Fluidized Catalytic Cracking Catalysts

Cited by 31 publications

References 39 publications

Abatement efficiency and fate of EPA-Listed PAHs in aqueous medium under simulated solar and UV-C irradiations, and combined process with TiO2 and H2O2

Abatement efficiency and fate of EPA-Listed PAHs in aqueous medium under simulated solar and UV-C irradiations, and combined process with TiO2 and H2O2

Potentials of African Star Apple (<i>Chrysophyllum albidum)</i> Fruit Shell Adsorbent in Recovery of Valuable Hydrocarbons for Spent Engine Oil

Selective C−C Hydrogenolysis of Alkylbenzenes to Methylbenzenes with Suppression of Ring Hydrogenation

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