TY - JOUR
T1 - Interaction between sulfated zirconia and alkanes
T2 - Prerequisites for active sites - Formation and stability of reaction intermediates
AU - Li, Xuebing
AU - Nagaoka, Katsutoshi
AU - Simon, Laurent J.
AU - Lercher, Johannes A.
AU - Wrabetz, Sabine
AU - Jentoft, Friederike C.
AU - Breitkopf, Cornelia
AU - Matysik, Silke
AU - Papp, Helmut
PY - 2005/2/15
Y1 - 2005/2/15
N2 - Two sulfated zirconia catalysts were prepared via sulfation and calcination of zirconium hydroxide at 873 K; the zirconium hydroxide had been aged at room temperature for 1 h (SZ-1) or aged at 373 K for 24 h (SZ-2). SZ-1 was active for n-butane isomerization at 373 K; SZ-2 reached a similar performance level only at 473 K. Both materials contained about 9 wt% sulfate and were tetragonal. Because of a lower BET surface area (105 vs. 148 m2/g) SZ-1 featured a higher sulfate density, and XRD and EXAFS analysis showed larger (ca. 10 nm) and more well ordered crystals than for SZ-2. n-Butane TPD on SZ-1 showed a butene desorption peak at low temperature, whereas no obvious butene desorption was observed with SZ-2, suggesting that SZ-1 has a higher oxidizing power at low temperature than SZ-2. The number of sites capable of dehydrogenation are less than 5 μmol/g, because the differential heats of n-butane adsorption as measured by microcalorimetry were 45-60 kJ/mol for higher coverages, indicating weak and reversible interaction. TAP experiments describe the adsorption and desorption behavior of n-butane at different activity states and are the basis for a simple adsorption model. Reactant pulses and purge experiments show that the active species, presumably formed in an oxidative dehydrogenation step, are stable at the surface under reaction conditions.
AB - Two sulfated zirconia catalysts were prepared via sulfation and calcination of zirconium hydroxide at 873 K; the zirconium hydroxide had been aged at room temperature for 1 h (SZ-1) or aged at 373 K for 24 h (SZ-2). SZ-1 was active for n-butane isomerization at 373 K; SZ-2 reached a similar performance level only at 473 K. Both materials contained about 9 wt% sulfate and were tetragonal. Because of a lower BET surface area (105 vs. 148 m2/g) SZ-1 featured a higher sulfate density, and XRD and EXAFS analysis showed larger (ca. 10 nm) and more well ordered crystals than for SZ-2. n-Butane TPD on SZ-1 showed a butene desorption peak at low temperature, whereas no obvious butene desorption was observed with SZ-2, suggesting that SZ-1 has a higher oxidizing power at low temperature than SZ-2. The number of sites capable of dehydrogenation are less than 5 μmol/g, because the differential heats of n-butane adsorption as measured by microcalorimetry were 45-60 kJ/mol for higher coverages, indicating weak and reversible interaction. TAP experiments describe the adsorption and desorption behavior of n-butane at different activity states and are the basis for a simple adsorption model. Reactant pulses and purge experiments show that the active species, presumably formed in an oxidative dehydrogenation step, are stable at the surface under reaction conditions.
KW - Active sites
KW - Alkanes
KW - Isomerization
KW - Reaction intermediates
KW - Sulfated zirconia
KW - Transient measurements
UR - http://www.scopus.com/inward/record.url?scp=13644263292&partnerID=8YFLogxK
U2 - 10.1016/j.jcat.2004.11.045
DO - 10.1016/j.jcat.2004.11.045
M3 - Article
AN - SCOPUS:13644263292
SN - 0021-9517
VL - 230
SP - 214
EP - 225
JO - Journal of Catalysis
JF - Journal of Catalysis
IS - 1
ER -