Partial oxidation of methane and ethane over metal oxide catalysts /

Li+/NlgO and supported sodium-manganese oxide are two of the

Bibliographic Details
Main Author: Wang, Dingjun, 1962-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1995.
Subjects:
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Description
Summary:Li+/NlgO and supported sodium-manganese oxide are two of the
most promising catalysts for the conversion of methane via
the oxidative coupling reaction. The nature of the active
species was explored by a combination of kinetic measurements
and characterization of the physical properties of the
catalysts. The addition of Cl- ions to a Li+/MgO catalyst at
a ratio of CIALI > 0.9 significantly improves the yields of
ethylene that can be achieved during the oxidative
dehydrogenation (OXD) of ethane. This high activity for the
OXD of ethane is responsible for the large H4/C2H ratio
achieved in the coupling reaction over the same cataivst.
The enhanced C2 6 activity and selectivity of the catalyst
mainly results from the fact that Cl- removes most of the
strongly basic sites and promotes formation of weakly basic
sites. The formation of multilayers of Li2co3 is, therefore,
inhibited. The sintering of the catalyst and the C02
poisoning effect is also minimized. The active centers for
ethane OXD are believed to be associated with a thin layer of
Li2O that partially covers the LiCl crystallites. This Li2o
is a weakly basic site but is capable of activating ethane.
In most respects, the effects of Clions on the Li'/ZnO
catalyst parallel those that were observed for the Li'/MgO
catalyst. Carbon dioxide, either added to the reagents or
produced during the reaction, significantly improves the
hydrocarbon selectivity in the oxidative coupling of methane
(OCM) and the OXD of ethane. Carbon dioxide inhibits
secondary reactions of CH3- radicals and C2H4 with the
surface, probably at the strongly basic sites, of the Li+/MgO
catalyst. Regarding this positive effect on the selectivity,
chloride ions play a similar role to that of carbon dioxide.
A Mn/Na2WO4/Mgo catalyst was developed. At 800'C, I atm, and
using a CH4/02 ratio of ca. 8/1, a methane conversion of 20%
was achieved at a C2+ selectivity of > 80%, with no diluent
in the reagents, which is among the best catalytic results
yet achieved for the OCM reaction. Similar catalytic results
were observed over the corresponding SiO2-Supported
catalysts, demonstrating that a common active site is
involved. Sodium ions concentrate on the surface of the
catalyst and are required for the high selectivity.
Manganese ions, which are highly dispersed in a
Na2O/Na2o2/Na2CO3 surface phase, are believed to activate a
surface form of oxygen. The bulk lattice oxygen is not
involved in the catalytic reaction.
Item Description:Vita.
"Major Subject: Chemistry".
Physical Description:xv, 224 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references.