2018
DOI: 10.3390/catal8020077
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Effect of Support Pretreatment Temperature on the Performance of an Iron Fischer–Tropsch Catalyst Supported on Silica-Stabilized Alumina

Abstract: Abstract:The effect of support material pretreatment temperature, prior to adding the active phase and promoters, on Fischer-Tropsch activity and selectivity was explored. Four iron catalysts were prepared on silica-stabilized alumina (AlSi) supports pretreated at 700 • C, 900 • C, 1100 • C or 1200 • C. Addition of 5% silica to alumina made the AlSi material hydrothermally stable, which enabled the unusually high support pretreatment temperatures (>900 • C) to be studied. High-temperature dehydroxylation of th… Show more

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Cited by 18 publications
(21 citation statements)
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“…In fact, plasma techniques can successfully be used both during the catalyst synthesis period [ 34 ], and at the pre-treatment stage to activate the catalyst [ 35 ]. For example, as used in conventional calcination instead of applying excessively high pre-treatment temperatures such as 973–1473 K [ 36 ], the as used in conventional calcination, plasma-glow discharge (PGD) could be applied to lower the pre-treatment temperatures and still produce smaller Co metal nanoparticles (<7 nm) [ 37 ], with a significant improvement to metal dispersion as the particle size is shown to be a function of the PGD intensity [ 38 ].…”
Section: Introductionmentioning
confidence: 99%
“…In fact, plasma techniques can successfully be used both during the catalyst synthesis period [ 34 ], and at the pre-treatment stage to activate the catalyst [ 35 ]. For example, as used in conventional calcination instead of applying excessively high pre-treatment temperatures such as 973–1473 K [ 36 ], the as used in conventional calcination, plasma-glow discharge (PGD) could be applied to lower the pre-treatment temperatures and still produce smaller Co metal nanoparticles (<7 nm) [ 37 ], with a significant improvement to metal dispersion as the particle size is shown to be a function of the PGD intensity [ 38 ].…”
Section: Introductionmentioning
confidence: 99%
“…Among the solvents tested, EtOH gave the best result at 80°C. Subsequently, the reactions were carried [27] 2 2 93 255-260 [28] 3 3.5 72 208-212 [27] 4 2 88 162-165 [27] 5 3.5 78 177-180 [28] 6 1.5 95 192-196 [27] 7 1.5 76 280-284 [2][3][4][5][6][7][8] 8 1.5 70 270-275 9 1.5 93 232-235 [27] 10 3 72 270-275 [a] Reaction conditions: aldehyde (2 mmol), α-naphthol (1 mmol), malononitrile (1.5 mmol), ammonium acetate (2 mmol), microsphere cobalt complex (50 mg), EtOH (2 mL), 80°C. [b] Isolated yield.…”
Section: Catalytic Studiesmentioning
confidence: 99%
“…Multi-component reaction (MCR) is a chemical reaction, which involve more than three reactants in one-pot reaction to form a product that incorporates essentially most or all atoms of the starting materials. [1][2] Among nitrogen-containing heterocyclic systems, functionalized pyrroloacridine-1(2H)-one derivatives have attracted the organic chemists interest due to their wide due to their interesting biological activities, such as antibacterial, [3] antitumor, [4] anthelmintic, [5] antifungal, [6] cytotoxicity, [7] and antiparasitic [8] compounds. Several methods of preparing acridine derivatives that the synthetic methods suffered disadvantages such as use of volatile organic solvents, harmful catalysts, low yields, and harsh reaction conditions, and expensive and difficulty in recycling the catalysts .…”
Section: Introductionmentioning
confidence: 99%
“…The nine contributions to this special issue come from former students, collaborators, colleagues, and respected peers. Keyvanloo et al's paper on Fischer-Tropsch catalysis [12] honors Professor Bartholomew's extensive contributions to this area. Hallac et al's spectroscopic study on iron-based water gas shift catalysts [13] hearkens back to Professor Bartholomew's graduate work with iron.…”
Section: The Contents Of the Special Issuementioning
confidence: 99%