Hydrodesulfurization of Dibenzothiophene Catalyzed by Supported Metal Carbonyl Complexes. (Part 6). Effects of Supports on Activities of HDS Catalysts Prepared from Supported Ruthenium Carbonyl-Cesium Hydroxide Systems.

Ishihara, Atsushi; Nomura, Masatoshi; Shirouchi, Kenji; Kabe, Toshiaki

doi:10.1627/jpi1958.39.403

Cited by 10 publications

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“…The values of krelease and S0 for these catalysts were estimated by similar methods described above, using these data, and are shown in Table 1. As described in the previous paper13)- 16), the conversion of DBT increased with increase in the amount of cesium added, reaching the maximum at Ru:Cs=1:2, while further addition of cesium decreased the conversion. Products were biphenyl (BP) and cyclohexylbenzene.…”

Section: Analyticalsupporting

confidence: 72%

Hydrodesulfurization of Dibenzothiophene Catalyzed by Supported Metal Carbonyl Complexes(Part 8) Hydrodesulfurization of 35S-Labeled Dibenzothiophene on Alumina-supported Ruthenium Sulfide-Cesium Catalysts.

et al. 1998

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In hydrodesulfurization (HDS) of 35S-labeled dibenzothiophene ([35S]DBT) catalyzed by alumina-supported ruthenium carbonyls-cesium hydroxide systems, the role of cesium was elucidated by tracing the behavior of 35S WHSV 14h-1, H2 18l/h, DBT 1wt%, precursor Ru3(CO)12-nCsOH/Al2O3 (n=0, 3, 6 or 9). During the reaction with sulfided catalysts, the changes in the radioactivities of unreacted [35S]DBT and product [35S]H2S with reaction time were monitored. The rate constant (krelease) of release of [35S]H2S was estimated from the first order plots of the increasing and decreasing radioactivities of product [35S]H2S. The values of krelease decreased with increase in the amount of cesium added, indicating that the mobility of sulfur on the catalysts decreased by the addition of cesium.On the contrary, the amount of labile sulfur on the catalyst (S0), which was calculated from the maximum amount of 35S accommodated on the catalyst, increased with increase in the amount of cesium added and reached the maximum at Ru:Cs=1:2, which was kept with further addition of cesium (Ru:Cs=1:3). This shows that the active sites on the catalyst were not poisoned because S0 did not decrease with the addition of excess amount of cesium.This maximum value of S0 at Ru:Cs=1:2 corresponds to RuS1.52. Assuming that ruthenium species are present as RuS2, 76% of sulfur on the catalyst is labile. This indicates that the dispersion of ruthenium species could be significantly high. Further, it is suggested that cesium promoted the C-S bond scission of DBT and increased the activity by stabilizing Ru-S bonds for ruthenium sulfide. IntroductionRecently, deep desulfurization of light gas oil has been one of urgent researches in the world and much attention has been focused on the development of new catalyst for deep desulfurization1),2). Among a number of attempts made to develop the new catalyst, nonsupported3)-5) and supported6)-12) ruthenium sulfides were found to be the most active for hydrodesulfurization (HDS) of thiophenes in transition metal sulfides. Pecoraro and Chianelli3) initially reported that ruthenium sulfide is the most active for HDS of dibenzothiophene (DBT) among the transition metal sulfides. Supporting ruthenium sulfide appropriately is an attractive approach to increase catalytic activity. Harvey and With these catalysts, however, the HDS activity was rather low, probably because sulfidation of ruthenium species was incomplete and RuS2 is unstable on a support in hydrogen atmosphere. Further, these HDS reactions were performed in atmospheric pressure, and so far the activities of supported ruthenium sulfide in a pressurized flow system have not yet been clarified in comparison with those of Co-Mo/Al2O3and Ni-Mo/Al2O3. Recently, the authors reported that, in HDS of dibenzothiophene (DBT), the catalysts derived from supported metal carbonyls showed catalytic activity higher than those from conventional catalysts11),12). The cesium promoted ruthenium catalysts revealed that the activity is comparable with that of conventional Co-Mo...

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Section: Analyticalsupporting

confidence: 72%

Hydrodesulfurization of Dibenzothiophene Catalyzed by Supported Metal Carbonyl Complexes(Part 8) Hydrodesulfurization of 35S-Labeled Dibenzothiophene on Alumina-supported Ruthenium Sulfide-Cesium Catalysts.

et al. 1998

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“…Among a large number of attempts, much attention has been focused on unsupported ruthenium sulfides, which were found to be the most active species in hydrodesulfurization of thiophenes using transition metal sulfides [1][2][3][4][5]. Actually, some of our recent studies aimed at optimizing ruthenium-based catalysts by different ways: investigation of the effect of the precursor [6]; addition of alkali [7]; and modification of the carrier [8]. These efforts permitted us to improve the HDS ability of the Ru sulfidebased catalysts.…”

Section: Introductionmentioning

confidence: 99%

Inhibiting effect of H2S on the DBT HDS activity of Ru-based catalysts—effect of the Cs addition

Ishihara

Lee

Dumeignil

et al. 2004

Journal of Catalysis

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“…However, γ-Al 2 O 3 is resistant to mass-transfer diffusion and has an overly strong metal–support interaction . Replacing the Al 2 O 3 with a more acidic or neutral support has been reported, with materials such as SiO 2 , zeolite, TiO 2 , ZrO 2 , and also the combination of two including Al 2 O 3 –SiO 2 , Al 2 O 3 –TiO 2 , Al 2 O 3 –B 2 O 3 , Al 2 O 3 –MgO, Al 2 O 3 –ZrO 2 , and so on. − Support materials are now tailored depending on the heavy oil’s nature for achieving the optimal upgrading results. − Other catalytic materials that showed excellent efficacy for sulfur and nitrogen removal are metal carbides (e.g., Mo 2 C), metal nitrides (e.g., Mo 2 N), and metal phosphides (e.g., Ni 2 P) . Noble metals such as Pt, Pd, Ru, and Ir also have excellent HDS and HDN activity .…”

Section: Overall Status Of Heavy Oil Hydrotreatmentmentioning

confidence: 99%

A Review on the Reaction Mechanism of Hydrodesulfurization and Hydrodenitrogenation in Heavy Oil Upgrading

et al. 2021

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The future of fuel supply will undoubtedly involve the utilization of heavy crude oils, including those from nonconventional sources, such as bitumen and oil shale. Because of their dense nature and poor compositional characteristics, heavy oils cannot be admitted straightly as refinery feeds, since the direct processing of such oils hardly produces engine fuels of commercial standard. The currently available refinery setups also require substantial retrofitting in order to process such heavy feeds. Thus, heavy oils must undergo an initial upgrading called hydrotreatment (HDT) by which the feeds are converted to qualified fuel oils or synthetic crude (syncrude) for easy handling. Removing the considerable amount of sulfur (S) and nitrogen (N) compounds present in the heavy crude oils selectively by hydrodesulfurization (HDS) and hydrodenitrogenation (HDN), respectively, is among the most critical and challenging aspects of the upgrading. However, the mechanism of these two reactions, in relation to different catalytic sites, temperature, pressure, and other operation variables, is not fully understood or well-documented. By analyzing the possible reaction routes involved in S and N removal by HDT, this review sets to bridge the gap that has been left void for a long period of time, to serve as a guide for innovative heavy crude oil upgrading technologies. It finally reports the current challenges impeding the speedy inclusion of heavy crude oils into the global oil supply stream, and proffer perspective solutions together with future research trends.

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Hydrodesulfurization of Dibenzothiophene Catalyzed by Supported Metal Carbonyl Complexes. (Part 6). Effects of Supports on Activities of HDS Catalysts Prepared from Supported Ruthenium Carbonyl-Cesium Hydroxide Systems.

Cited by 10 publications

References 0 publications

Hydrodesulfurization of Dibenzothiophene Catalyzed by Supported Metal Carbonyl Complexes(Part 8) Hydrodesulfurization of 35S-Labeled Dibenzothiophene on Alumina-supported Ruthenium Sulfide-Cesium Catalysts.

Hydrodesulfurization of Dibenzothiophene Catalyzed by Supported Metal Carbonyl Complexes(Part 8) Hydrodesulfurization of 35S-Labeled Dibenzothiophene on Alumina-supported Ruthenium Sulfide-Cesium Catalysts.

Inhibiting effect of H2S on the DBT HDS activity of Ru-based catalysts—effect of the Cs addition

A Review on the Reaction Mechanism of Hydrodesulfurization and Hydrodenitrogenation in Heavy Oil Upgrading

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