Post on 30-Dec-2015
Sigma-bond metathesis
Textbook H: Chapter 6.5.1 – 6.5.2
Textbook A: Chapter 3.3.7
[M]-CR3 + H-E [M]-E + H-CR3[M]
CR3
H
E
Sigma-bond metathesis
It avoids the TD barriers of the C-H activation /substitution step.
It is found for early TM with d0 configuration.
Lu CH3
+ CH4
- CH4
LuCH3
H
CH
H
H
Lu
H3C
H
C
H H
H
++-
-
Cp*2Lu-CH3 + H-13CH3 Cp*2Lu-13CH3 + H-CH3Cp2*Lu
CH3
H
13CH3
Cp*2Lu-CH3 + H-CH3 Cp*2Lu-CH3 + H-CH3
Cp*2Lu-CH3 + H-H Cp*2Lu-H + H-CH3
Cp*2Lu-CH3 + H-CH3 Cp*2Lu-H + CH3-CH3does not give
Cp*2Lu-H + H-H Cp*2Lu-H + H-H
Cp*2Lu-H + H-CH3 Cp*2Lu-H + H-CH3does not give
+ H-CH3H
La
Cp Cp
HLa
Cp Cp
H
CH3
H
La
Cp Cp
H3C H
0 kcal/mol
73.2 kcal/mol
15.5 kcal/mol
+ H-SiH3H
La
Cp Cp
HLa
Cp Cp
H
SiH3
H
La
Cp Cp
H3Si H
0 kcal/mol
-3.6 kcal/mol
2.8 kcal/mol
Why position cannot be CThe reaction is best described as a nucleophilic substitution of H at either C or Si in the coordination sphere of Ln.
The energy barrier for C at the position is lowered with electronegative substituents (F), known to stabilize a hypervalent species, but not vinyl or phenyl.
The transition state is a pentacoordinated anionic CH5
- or SiH5- which is energetically
highly unfavorable for C and much more favorable for Si.
-H elimination
-hydride elimination as the reverse of -bond metathesis
4
Cp
ThCp
tBu
tBu
Cp
ThCp
tBu
Cp
ThCp
tBu
CH2
-agosticinteraction
H
Cp
ThCp
tBu
CH2
H
-bondmetathesis
starting
-bondmetathesis
ending
50 oC, 60 h-H elimination
bond metathesis with high-valent, late TMs Midterm 2005: Recently, Hartwig et al. (J. Am. Chem. Soc. 2005, 127, 14263-
14278) published mechanistic studies on the functionalization of arenes by diboron reagents catalyzed by iridium complexes:
5
For each step shown in the catalytic cycle indicate the mechanism (type of reaction). Where you can envision more than one possibility, write down all of them (at least two) discussing arguments that support your proposal or that are against it (at least one of each). If you consider that some intermediates are not shown, draw those intermediates. Indicate formal oxidation state and electron count for each iridium complex.
Electrophilic activation of C-H bonds
Shilov, 1972
Alkane activation step
Pd2+, Pt2+ and/or Pt4+, Hg2+, Tl3+.
LnMx+2X2 + R-H LnMx + R-X + H-X
LnMx+2X2 + R-H LnMx(R)(X) LnMx + R-X- HX
CH4 + D2OPtCl4
2-
CH3D + HDOD2O / CH3COOD
CH4 + PtCl62- + H2O (Cl-)
PtCl42-
H2O120 oC
CH3OH (CH3Cl) + PtCl42- + 2 HCl
(II)Pt
H2O
Cl OH2
Cl
+ CH4
- HCl
(II)Pt
H2O
Cl OH2
CH3
+ Pt(IV)Cl62-
- Pt(II)Cl42-
PtH2O
Cl OH2
Cl
CH3
Cl
H2O-CH3OH
-HClPt(II) + R-H
Pt(II)H
R
Pt(IV)
H
R
Pt(II)-R + H+
1,2-AdditionM=N bonds
M=C bonds
X
Zr
XR
NHtBuX
Zr
X
NtBu- RH + R'H
X
Zr
XR'
NHtBuX = Cp: Bergman
X = NHtBu: Wolczanski
1988
Mo NO - C6H6Mo NO
Mo NO
- CMe4
Mo NOL
L
Mo NOR
HH
RHL
Mo NOR
RH
MoNOL
H
Legzdins, 2003
-H elimination -hydride elimination as the reverse of 1,2-addition
8
LnMHC
H
R
-H eliminationLnM
CHR
H
Li
tBu
Ta
Cl
CltBu
tBu
tBu
Zn
tBu
2Ta
tBu
tBu
tButBu
tBuHH
HH
Ta
tButBu
tBu
tBu
TaCl53 -H elimination
not isolated
Migratory insertions
U
M XM U X
U = CO, C2H4, C2R2, NO, CR2, CNR, RCN, O2, CO2
X = H, alkyl, aryl, OR, NR2
Migratory insertions
Two possible mechanisms:
Labeling studies show that Me migrates.
10
Me
M COM C
Me
O
C
M
Me O
Me migratesCO migrates
MnOC
OC 13CO
CO
C
CO
O Me
if CO movesMn
OC
OC CO
CO
Me
CO
25%no label
+ MnOC
OC 13CO
CO
Me
CO
75%
Me is cis tothe label only
MnOC
OC CO
CO
Me
CO
25%no label
+ MnOC
OC 13CO
CO
Me
CO
50%cis
MnMe
OC 13CO
CO
CO
CO
25%trans
+
if Me moves
cis : trans2 : 1
U
M XM U X
U = CO, C2H4, C2R2, NO, CR2, CNR, RCN, O2, CO2
X = H, alkyl, aryl, OR, NR2
experimental results
If CO moves
11
MnOC
OC 13CO
CO
C
CO
O Me
MnOC
OC CO
CO
Me
CO
25%no label
+
MnOC
OC 13CO
CO
Me
CO
75%
MnOC
OC
CO
C
CO
O Me
- 13CO
25%
MnOC
13CO
CO
C
CO
O Me
- CO
+
75%
CO moves
CO moves
If Me moves
12
MnOC
OC 13CO
CO
C
CO
O Me
MnOC
OC Me
CO
CO
CO
25%no label
+
MnOC
Me 13CO
CO
CO
CO50%cis
MnMe
OC 13CO
CO
CO
CO
25%trans
+
MnOC
OC
CO
C
CO
O Me
- 13CO
25%
MnOC
13CO
CO
C
CO
O Me
- CO
+
75%
Me moves
Me moves
Migratory insertion examples
Insertion of CS2
(OC)5Mn R + CS2 (OC)5MnS
RS
Insertion of SO2
(OC)5Mn R + SO2 (OC)5Mn S R
O
O
S-bound
Cp2TiMe2 + SO2 S Me
O
O-boundOCp2Ti2
Reactions of alkyls with electrophiles
LnMCH2 CH2
H -H elimination
LnM
H
H2C
CH2LnM H H2C CH2+
-H elimination: retro-migratory insertion
-Olefin insertion
• -olefins can insert from two positions:
1,2-insertionR
1-position
2-position
ZrMe
ZrMe
ZrMe
R
RR
Zr
RMe
ZrMe
ZrMe
ZrMe
R
Zr
MeRR
R
2,1-insertion
• 1,2-addition is the major mode of insertion; 2,1-insertion usually leads to chain termination in polymerization reactions.
elimination: retro-migratory insertion
Modes of blocking -H elimination No -hydrogens The alkyl is oriented so that the beta position cannot access the metal
center (steric bulk or rigidity). The alkyl would give an unstable alkene as the product.
15
CMe3
M
neopentyl
CMe2Ph
M
neophyl
SiMe3
M
"silyl-neopentyl"Ph
M
benzyl
M R
M
alkynyl
norbornyl
LnMCH2 CH2
H -H elimination
LnM
H
H2C
CH2LnM H H2C CH2+