POTASSIUM DISPERSION ON SILICA-SUPPORTED RUTHENIUM CATALYSTS

被引：31

作者：

HOOST, TE ^{[1
]}

GOODWIN, JG ^{[1
]}

机构：

[1] UNIV PITTSBURGH, DEPT CHEM & PETR ENGN, PITTSBURGH, PA 15261 USA

来源：

JOURNAL OF CATALYSIS | 1991年 / 130卷 / 01期

基金：

美国国家科学基金会;

关键词：

D O I：

10.1016/0021-9517(91)90110-P

中图分类号：

O64 [物理化学（理论化学）、化学物理学];

学科分类号：

070304 ; 081704 ;

摘要：

Alkali modifiers are known to be quite effective at improving catalyst activity or selectivity for several metal-catalyzed reactions of industrial importance. Yet it is still difficult to address the location and distribution of alkali species in most catalysts. This paper reports on an investigation of the potassium dispersion in a series of 3 wt% Ru/SiO2 catalysts sequentially doped with potassium nitrate up to (K/Ru)awm = 0.2 followed by rereduction. This series was evaluated extensively using gas volumetric hydrogen chemisorption and the structure-sensitive ethane hydrogenolysis reaction. Hydrogen chemisorption results indicate that the alkali was apparently atomically dispersed on the ruthenium surface. The added potassium species interfered with hydrogen chemisorption on a one-to-one atomic basis. Potassium addition resulted in a decrease in the apparent activation energy and an increase in the apparent hydrogen reaction order for ethane hydrogenolysis. Using the statistical poisoning model of Martin (Catal. Reu.-Sci. Eng. 30, 519 (1988)) which assumes that the metal surface is uniform for adatom adsorption, the apparent ensemble required for the reaction was estimated to be made up of 12 ± 3 adjacent exposed surface ruthenium atoms. Using an extension of Martin's model, this structure-sensitive reaction also revealed that at the higher potassium levels the alkali dispersion became nonuniform. This nonuniform dispersion is suggested to be due to a preference of the dopant for certain metal sites. Because of this nonuniform dispersion, the true" reaction ensemble size is suggested to be less than 12. © 1991."

引用

页码：283 / 292

页数：10

共 48 条

[1] SUPPORT AND PROMOTER EFFECT OF RUTHENIUM CATALYST .1. CHARACTERIZATION OF ALKALI-PROMOTED RUTHENIUM ALUMINA CATALYSTS FOR AMMONIA-SYNTHESIS [J].

AIKA, K ;

SHIMAZAKI, K ;

HATTORI, Y ;

OHYA, A ;

OHSHIMA, S ;

SHIROTA, K ;

OZAKI, A .

JOURNAL OF CATALYSIS, 1985, 92 (02) :296-304

[2] THE ROLE OF POTASSIUM AS A PROMOTER IN IRON CATALYSTS FOR AMMONIA-SYNTHESIS [J].

ALTENBURG, K ;

BOSCH, H ;

VANOMMEN, JG ;

GELLINGS, PJ .

JOURNAL OF CATALYSIS, 1980, 66 (02) :326-334

[3] COADSORPTION AND PROMOTER EFFECTS IN THE ADSORPTION OF CO ON SUPPORTED RHODIUM CATALYSTS [J].

ANGEVAARE, PAJM ;

HENDRICKX, HACM ;

PONEC, V .

JOURNAL OF CATALYSIS, 1988, 110 (01) :18-22

[4] COADSORPTION AND PROMOTER EFFECT IN THE ADSORPTION OF CO ON PALLADIUM CATALYSTS [J].

ANGEVAARE, PAJM ;

HENDRICKX, HACM ;

PONEC, V .

JOURNAL OF CATALYSIS, 1988, 110 (01) :11-17

[5] THE EFFECTS OF CS PROMOTION ON RH/AL2O3 CATALYSTS [J].

BLACKMOND, DG ;

WILLIAMS, JA ;

KESRAOUI, S ;

BLAZEWICK, DS .

JOURNAL OF CATALYSIS, 1986, 101 (02) :496-504

[6] X-RAY PHOTOEMISSION SPECTROSCOPY OF POTASSIUM PROMOTED FE AND PT SURFACES AFTER H-2 REDUCTION AND CO/H-2 REACTION [J].

BONZEL, HP ;

BRODEN, G ;

KREBS, HJ .

APPLICATIONS OF SURFACE SCIENCE, 1983, 16 (3-4) :373-394

[7]

Boudart M., 2014, KINETICS HETEROGENEO

[8]

Boudart M., 1969, ADV CATAL, V20, P153, DOI DOI 10.1016/S0360-0564(08)60271-0

[9]

BOWKER M, 1981, SURF SCI, V108, P299

[10] ACTIVE-CENTERS OF PLATINUM-SILICA CATALYSTS IN HYDROGENOLYSIS AND ISOMERIZATION OF NORMAL-PENTANE [J].

BRUNELLE, JP ;

SUGIER, A ;

LEPAGE, JF .

JOURNAL OF CATALYSIS, 1976, 43 (1-3) :273-291

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