Table Of Content1
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1 Catalytic Activation
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Catalytic Activation
of Carbon Monoxide
Peter C. Ford, EDITOR
University of California
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8 Based on a symposium
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9 Second Chemical Congress of the
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August 25-27, 1980.
ACS SYMPOSIUM SERIES 152
AMERICAN CHEMICAL SOCIETY
WASHINGTON, D. C. 1981
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5 Catalytic activation of carbon monoxide.
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1-0 (ACS symposium series, ISSN 0097-6156; 152)
98 Includes bibliographies and index.
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k- 1. Catalysis—Congresses. 2. Carbon monoxide—
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1/ Congresses. 3. Chemistry, Organic—Synthesis—Con
02 gresses.
0.1 I. Ford, Peter C. II. American Chemical Society.
1 Division of Inorganic Chemistry. III. Chemical Con
oi: gress of the North American Continent (2nd: 1980:
1 | d Las Vegas, Nev.). IV. Series.
98 TP156.C35C39 661'.8 81-1885
5, 1 ISBN 0-8412-0620-1 ACSMC8 152 1-35A8 A1C9R821
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blic American Chemical Society
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PRINTED IN THE UNITED STATES OF AMERICA
ACS Symposium Series
M. Joan Comstock, Series Editor
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1- Advisory Board
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1 | d Donald D. Dollberg Leon Petrakis
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James D. Idol, Jr. Gunter Zweig
01 FOREWORD
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15 The ACS SYMPOSIUM SERIES was founded in 1974 to provide
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1 format of the Series parallels that of the continuing ADVANCES
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02 papers are not typeset but are reproduced as they are sub
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oi: viewed under the supervision of the Editors with the assistance
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1 | of the Series Advisory Board and are selected to maintain the
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19 integrity of the symposia; however, verbatim reproductions of
y 5, previously published papers are not accepted. Both reviews
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ate: embrace both types of presentation.
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PREFACE
The catalytic activation of carbon monoxide is a research area currently
receiving major attention from academic, industrial, and government
laboratories. There has been a long standing interest in this area; however,
the new attention obviously is stimulated by concerns with the present and
future costs and availability of petroleum as a feedstock for the production
of hydrocarbon fuels and of organic chemicals. One logical alternative
source to be considered is "synthesis gas," mixtures of carbon monoxide
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0 and hydrogen that can be produced from coal and other carbonaceous
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2. materials.
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0 Potential applications of synthesis gas include conversion to liquid
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8 fuels via the Fischer-Tropsch reaction, production of hydrogen via the
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k- shift reaction (for ammonia manufacture and for the direct liquifaction
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1/ of coal) and the production of methanol, ethylene glycol, and other
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1 oxygenated organic chemicals. Efficient catalysts for such processes need
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oi: 1 to be designed and their fundamental reaction mechanism chemistry under
d stood. The symposium was organized to focus on these questions. The
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8 major emphasis was directed toward homogeneous catalysis; however,
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5, several authors addressed the question of characterizing catalysis pathways
ay on surfaces. The chapters included in this volume comprise the major part
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Dat The symposium was sponsored by the Inorganic Division of the American
on Chemical Society and also received some financial support from the
cati Chevron Research Company, for which the Editor is grateful.
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PETER C. FORD
Santa Barbara, California
November 30, 1980
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1
Activation of Carbon Monoxide by Carbon and
Oxygen Coordination
Lewis Acid and Proton Induced Reduction
of Carbon Monoxide
D. F. SHRIVER
Department of Chemistry, Northwestern University, Evanston, IL 60201
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a In its free state, carbon monoxide is highly resistant to
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at The reactivity of coordinated CO is much greater than that of the
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n free molecule and metal surfaces are in general even more effec
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ati tive than simple coordination compounds in promoting CO reduc
blic tion. One great challenge to the inorganic chemist is to make
Pu the connection between chemistry which occurs on the surfaces of
metals and the more readily studied reactions of discrete molecu
lar organometallics. One possible mode of CO activation which
has been invoked in heterogenous catalysis is C and O bonding to
a surface. This bifunctional activation of CO may lead to CO
cleavage and eventual incorporation of a surface carbide into
organic products, or to direct incorporation of the C and O coor
dinated CO into an organic group (1-3). Bifunctional activation
also is thought to be important in molecular systems (4,5), but
it is fair to say that the evidence for, and understanding of
this phenomenon has been very rudimentary. In this paper we pre
sent the results of studies at Northwestern which were designed
to provide clear-cut evidence for bifunctional CO activation in
molecular systems and to provide information on the important
0097-6156/81/0152-0001 $05.00/0
© 1981 American Chemical Society
2 CATALYTIC ACTIVATION OF CARBON MONOXIDE
chemical variables in these reactions. We first describe Lewis
acid promotion of the alkyl migration (CO insertion) reaction,
including recent results on the combination of this acid promoted
alkyl migration reaction with CO reduction. This repetitive
sequence of CO insertion and carbonyl reduction provides a means
of building hydrocarbon chains under mild conditions. Finally,
proton induced CO reduction will be described, and the most
recent mechanistic information on this reaction will be pre
sented. As a prelude to these discussions, we outline two fun
damental reactions of coordinated CO.
Electrophilic and Nucleophilic Attack of Coordinated CO
The attack on coordinated carbon monoxide by nucleophiles was
first extensively developed in synthetic organometallic chemistry
01 by E. 0. Fischer and his students (6); as discussed by others in
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52. coordinated CO and to catalysis of the water gas shift reaction.
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8 philes are electron deficient, as judged by their high CO
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d and a variety of physical evidence indicate that a low CO
1 | stretching frequency corresponds to high electron density on the
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19 CO iigand (8). Carbonyl groups in this category include bridging
5, carbonyls, terminal carbonyls in metal carbonyl anions, and ter
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Ma minal carbonyls in donor substituted metal carbonyls, structures
e: la through lc. The attack on bridging carbonyls by electrophilic
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C L 0 C
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1. SHRIVER Lewis Acid and Proton Induced Reduction 3
reagents is a common feature of the chemistry of polynuclear
carbonyls, and it may lead to a variety of CO rearrangements
(8^,9^). One striking physical effect of Lewis acid addition to
the oxygen end of CO is a very large reduction in the CO
stretching frequency, which implies a large decrease in CO bond
order, Figure 1 (10). This phenomenon will be discussed in more
detail at the end of the paper, and for the present it will
suffice to point out that the addition of a Lewis acid to the
carbonyl oxygen favors carbene-like resonance structures, which
arise from the polarization of the 7r system, equation 2.
LM-C=0 + A1X > L^C-0^ (2)
n 3
AIX3
The very large perturbing influence of C and 0 bonding on
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10 carbonyl reaction other than substition (11-13). As shown in
10. equation 3a, the currently
doi: R
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ate: alkyl group onto a coordinated CO, to yield a coordinatively
D unsaturated metal acyl intermediate (which perhaps may be solvent
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cati ligand to produce a stable acyl complex, equation 3b. When a
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v*-c; + L' ^ef v-'*-^ (3b)
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stable product is formed, k_ « k, ttie kinetic expression takes
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the form given in equation 4, with two limiting conditions,
equations 5a and 5b.
k ^ f L ' H L ^ C O )]
r a te = k. + k[L'] ( 4)
x 2
rate = Kk[Lf][LMR(C0)] when k[Lf] « k. (5a)
2 n 2 x
rate = k[LMR(C0)] when k[Lf] » k_ (5b)
1 n 2 x
Description:Content: Activation of carbon monoxide by carbon and oxygen coordination : Lewis acid and proton induced reduction of carbon monoxide / D.F. Shriver -- Experimental and theoretical studies of mechanisms in the homogeneous catalytic activation of carbon monoxide / H.M. Feder, J.W. Rathke, M.J. Chen,
