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Zinc annual survey covering the year 1971
77
ZINC ANNUAL
SURVEY
COVERING
THE
YEAR
1971
Utrecht
(The
Jan G. Nolte s Organis
ch Chemis
ch Instituut
TNO,
Netherlands)
CONTENTS
I.
Preparation
II.
Reactions
of organozinc
of organozinc
A.
Reformatsky
B.
Reactions -carbon
C.
reaction
and related
reactions
Organozinc
compounds
IV.
Structural,
spectroscopic
A.
Structural
B.
Spectroscopic
C.
Other
atom
82
reactions
and alkenylzinc
and carbon-hetero
III.
82
compo?mds
of alkylzinc
Carbenoid
77
compounds
compounds
unsaturated
of organozinc
with
carbon-
bonds
90
compounds
as polymerization
and physical
100
catalysts
105
studies
109 109
studies
110
studies
physical
studies
112
References
I.
112
PREPARATION The
new
1971
organozinc
Referencesp. 112
OF
ORGANOZINC
literature compounds
contains
COMPOUNDS relatively
or new types
few
references
of organozinc
dealing
complexes.
with
78
J.G.NOL~ Lorberth
metal
has published
derivatives
acidolysis
the details of his synthesis Such
of diazoalkanes.
of the very
with diazomethane
reactive
compounds
were
bis(trimethylsilylamino)
or ethyldiaeoacetate
of Group
:.._'-
II B
_~
obtainedby derivatives
LlJ: I
Zn:N(SiMe3)
?!I
ZniN(SiMy)2d2
2
.:
+
CH$$
g%+
+
2HC(N$OOEt
,bnCN2],
%!%
+
. .
ZHN(Si&),
Zn[C(N2)COOEq2
f
+
ZHN(SiMe) 32
Noveltrinuclear characterized spontaneous
by Bdersma
+
n acac'
1
of the
benzene
Hacac
+
S-diketonate
et al. Complexes
disproportionation
P$Zn
2phZ
phenylzinc
P
Ph2Zn
oftype
t
have
been
(I) are formed
Ph2Zn/S-diketone
iPhZnaca4.
f
complexes
via
l/l reaction
PhH
Zn(acac)2
i’
2 :FhZnacaci ‘L +
Zn(acac)2
_3
'PhZnacac]2. !_
Zn(acac)2
(I)
product mixed
or by a stoechiometric
reaction
which
allows
the isolation of
complexes:
.
2PhZnpac
+
Zn(acac)2
w
[PhZn pad 2. Zn(acac)2
-_.
79
ZINC For
(I) a structure
coordinate
terminal
Kawakami weight,
and
e.g.
data)
+
shown
carbonyl
using
f
been
reported
as well
zinc
proposed
of the products
(BuZ2.n
Aminophosphine
P%Zn
have
C%(GOOMe)2
were
o, g-unsaturated
synthesized
has
central [
a study formed
as
-dimethylsilane
b
to undergo compounds
derivatives
BuZnX)
(analytical,
molecular
with active
RNHPP%
%%
MeOZnCH(COOMe)2
a Michael-type
of
methylene
l/l acts
atom
of dimethyl-
baur
and Wolfsberger
complexes as
a
reaction
in which
and diethylzinc
BuH
1,4-addition
compounds
with
have
been
4 -
rJ-
PhZnNRPP%
1,3-bidentate
+
i-31=
of organozinc
an acidolysis-type
zinc
Referencesp. 112
Zj.
by the interaction
f
(R = 2,3-Me&,?,
Crystalline
and two tetra-
:
BuZnOMe
products
atoms
Tsuruta
compounds
compounds,
one hexacoordinate
zinc
IR and NMR
n-butylzinc
Such
with
PhH 4-MeC6H4,
2-pyridyl)
bis-trimethylphosphinimoligand
have
to the tetracoordinate
been
reported
by Schmid-
-80
Me
%
Zn
+
/
M?P=N
(Me,P=N),BiMe2
R
Various
reports
hydridozinc
complexes
Tsuruta wards
carbon
rated
dealing
ketones
et al.
have have
\
‘Zn’ 11
N=PMe3
R
of anionic
the synthesis
and a variety
of saturated
tetra-n-butyl
and Travers
have
and reactivity
CaZn(nkBu)4
reported
anionic
zinc,
of the dodecahydro-nido-decaborate(2-)
[7].
complexes
which
obtained
by ionization
2 ZnB10H12-2
yields
reaction
a compound
2CH3ZnI
isolated
+
3NaH
in water
results
Et20
of the neutral
is a bis-ether
%%
of methylzinc
+
ion
salts
compound
are
which
readily according
complex:
ZnZf
+
iodide
of the composition
cadmium
as the bis-(trimethyl-
or the bis-(methyltriphenylphosphonium)
to new analytical
The
were
to-
[61. _
complexes
ammonium)
or
and o, @-mnsatu-
and mercury Th e zinc
alkylzinc
appeared.
of calciumzinc
Greenwood
Bi’
with the synthesis
investigated
tetrachloride
Me
Zn(B10H12)‘-
with
sodium
NaZn2(GH3)2%
NaZn2(C’H3)2H3
f
+
hydride for
4 Et20
in THF
which
the
2NaI
(11) following
structures
were
considered
kj
_. H “3-Z++,
‘‘;r n-C%
H
: I_.*. .
ZINC
81
J
Reductions with
with this
reductions
LiAlH4,
precursor high
hydride
converts
NaZnH3
The and
Beach
has
NaZnE$:
zinc
or
THF
4KH
2KZn(sec-Bu)3
diethylether
diethylether reaction
Referencesp. 112
of potassium
2
+
to
f
stability
than
been
hydride
(II) is a
heating
(CI-$),Zn
has
%nH2 I8 _ -‘.
obtained
with
under
xTHF
by Ashby
di-sec.butylzinc
of the anionic
K2ZnH4
-
the
is
quite
reaction
complex
2 KZn(sec-Bu)3
+
Zn
thermally
of zinc
as a route
of the thermal energy
+
K,ZnH4
unsuitable
an activation p 11.
-
K2ZnH4
found
at -45-50° study
Zn
3 l5
ZnH2
authors
a kinetic
thermal
K2ZnH4
facile.
Moderate
+
obtained
[S ,: _ i
-I- 3 (see-Bu)
Russian
of zinc.
and by the hydrogenation
in THF
In contrast
greater
to those
particularly
NaZnH3
hydride
by the reaction
KZn(sec-Bu)3
this
(II) into
somewhat
quaternary
in benzene
From
hydride
4
similar
being
ternary
THF
N~Zn(C~),~.x
results
of nitriles
to the first
vacuum
afford
of 27.9
Kcal/mole
6 C4H10
stable
iodide
to zinc
decomposition
+
with
hydride of-zinc was
[9j.
LiAlH4
in
$Oj_ hydride
obtained
in for
82
J-G_ NOLTE$
II.
REACTIONS
A.
Reformatsky The
remained
this
research,
past
reaction
year
of functionally
which
has
new
and related aspects
have
perature
in benzene
observed
that
vent
procedure
containing
8-hydroxy
allows
conditions,
e.g.
dilute HCl
BrZnC%C
Ph\
Stereo-
Rathke
at room
yields
may
be obtained
when the carbonyl l2 13
o-bromoesters of
The
and,
compound
/ \
of this
is’especially
. of alkyl
8-hydroxyacids. under
o-
The primary
extremely
mild
-0 OSi Me3
C(OH)C%COOH
carbaethoxymethyl
reaction group
has
(80%)
been
applied
in organosilicon
more
when a sol-
advantage
instead
hydrolyzed
tem-
and Lindert
temperature
is used,
synthesis
at reflux
Et/
The Reformatsky of the
In the
:r 3]: i.
+
_
In
chemists,
in the literature.
conducted
condensation
0 Ph-&-Et
of French
emphasized.
solvents.
trimethylborate
are
research.
attention.
readily
esters
reagents
of the Reformatsky
is normally
quantitative
a facile
trimethylsilyl
are
appeared
received
of trimethylsilyl
dbromoesters
the domain
applications
proceeds
apparent
organozinc
of organozinc
aspects
have
to base-catalyzed
The use
largely
synthetic
also
area
or benzene-ether
reaction
is most
susceptible
been
reaction
that nearly
mixture
active
reactions
The Reformatsky
important,
most
reactions substituted
than organometallic
numerous
chemical
COMPOUNDS
and related
the single
rather
reaction
ORGANOZINC
sllemistry
has
organic
OF
for
the introduction
k4],
organogerma-
..
ZINC
83
c-*
niUm
151 and
'?MX
organotin
+
E.g.
is used
compounds:
3
ZnBrCH2COOEt
Nitrones furan
$4
maybe
--+
appliedas
as the solvent
carbonyl
and
+
analogs
ZnBrX
whentetrahydro-
the reaction
temperature
react
zinc and
N-methyl-C-arylaldonitrones
to yield the corresponding
$MCH;?COOEt
with
is controlled, o-bromoesters
2-methyl-3-aryl-5-isoxazolidones
(III) '>6-: _ 2
\c//p \ /I
i
OEt
jN\ Me
OZnBr
/--
>
kjLc_&;, /
-BrZnOEt
\ c=o
MeANlO/ (III)
Several sation
reactions Luche
reaction nearly
studies
and
have
with
dealt with
Reformatsky
Kagan
have
with Schiff bases. quantitative
formation
(IV). At refluxtemperature formed
as well.
degree
of.reversibility
References p. 112
The
investigated The
the stereochemistry
preformed
of aminoesters
were
of conden-
reagents.
a certain
results
stereochemicalaspects
amount
reagents with
at -18O
react
with
erythro-configuration
ofthreo-isomer
interpretedinterms
for the condensation
of the
reaction
(V) is
of a certain . 17 :
11
.c
LG. NOLT+:-
84 ZnBr
I;I I ’
7
Phb&N-Ph
0
RCH-C” +.
I R----C-GOOR’
PhCH=N-Ph
-COOR’
A
H
I;.
(VI
(IV)
A_ stud?
of the stereochemistry
to Z-methylequatorial the order
ZnBr
1 Ph&-A--Ph
‘OR’
+ +-
I Rrr,&
sf
I
nBr
of addition
and 2-ethylcyclohexanone attack
the ratio
of 4jl
revealed
of Reformatsky a strong
to cis-epimeric
of -trans-
reagents
preference
alcohols
for
being
in
E8]:
f
.aR
0
BrZnCEI2C~
‘OR’
CL
w
, OH tE$COORl
This
is the trend
type
of addition
generally
coworkers
product
a .
threo-
compounds
H
* *
s
H
erythro-
derived
rapidly
(650/d isomers
-6
11.
that in DMSO
reagent
Ph
Ph--6-A--COOMe BrZnO
shown
and benzaldehyde
(35%).and
H
have
of the Reformatski
-bromophenylacetate of erythro-
by alkylzinc
for
this
(AS 69; 2231.
Blagoev-and densation
followed
from
equilibrates
$9j:
H
.
, I
Ph--C-C-COOMe Bri%O
at 45O the con-
A Ph A
threo-
methyl
o-
to a mixture
ZINC
The
85
same
authors
ary butylgroup (erythro/threo DMSO
that
observed
slightly favors the formation = 48/52)
at -5Othe
bi].
condensation
the Reformatsky
of the methyl
replacement
Gaudemar
of the erythro-isomer
et al. have shownthatin
of benzaldehyde
reagent derived from
by aterti-
or acetophenone
ethyl or propyl
with
o-bromobutyrate
is kinetically controlled [21]. The asymmetric reagents
has
been
realized
tion in an asymmetric mine) has made
synthesis of 8-hydroxyesters by carrying
which
Reformatsky
possible the synthesis of p-hydroxyester
reagent
as high as 98%.
was
dia-
with (S) con-
Application of the
in dimethoxymethaneincreasedthe
on the substituentgroups
depending
condensa-
solvent. The use of (-)spartein (a tertiary
figuration having optical purities preformed
out the
using achiral
opticalpur ity
in the order
of 35-98s
t22j. Reformatsky
reagents
undergo
with diethyl alkylidene malonates, yields of 52&O%
conjugate addition upon interaction 1,4-adducts
having beenisolatedin
k3]:
/ EtooCC?R’ CH---CH R'
A similar
1,4_additiontakes
allowing the preparation
Referencesp. 112
\
COOEt
COOEt
place with alkylidene cyanoacetates
in 50-60 yield of o-cyanoglutaric
esters
;241:
J.G. NOLTES
86
CH H R
\ /
CN
/
c=c
C
\
0
//
BrZnCH2C
\
COOEX
R--CH--CH IqzJ-+
1
halogen
bonds.
derived
from
C~-eooEt
been
undergo
A complete
reported
developed
reagents
ethyl
-.
‘Cody
Ol3
(R= Et, n-Pr,
Reformatsky
product
coupling study
o-bromobutyrate
and conditions
reactions
with
of the reaction
obtaining
(VI)
-.
i-Pr)
carbon
of the reagent
with bis(chloromethyl)ether
for
.’ :-. :
/
in 5545%
has
yield
were
p51:
2
K1=y20
The
synthesis
I?-60%
has
been
matsky
reagents
of esters effected
with
of substituted
by Russian
a-ketoesters
( EtOe+G%-!20
(r,ou
malic
workers
acids
via
in yields
condensation
of of Refor-
$26 :
1
0 Ph:COOR
+
BrZnCHR’COOR
PhC(OH)(COOR)CHR’COOR W (R=Me,
Several substituted matsky
papers organozinc
reagents Methyl
undergoes
have
dealing
compounds
synthetic differing
applications from
R’=H,
Me, Et)
of functionally
the traditional
Refor-
appeared.
Q’-bromocrotonate
conjugate
with
Et;
addition
affords
an organozinc
with diethyl
alkylidene
reagent malonates.
which A mix-
..
87
ZINC ture
of the products
ment)
(VII;
straight
addition)
and
(VIII;
allylic
rearrang-
is isolated
COOEt R-CH=C
/ \
+
BrZnCl-$-CH=CH~OOMe
COOEX
R-CH-CH(COOEt)2 7qF
R--CH-CH(COOEt)2
kH+H=CH--COOMe
I
+
CH2=CH-CH400Me
(VII)
(VIII) fR=Et,
Diethyl upon
dibromomalonate
condensation
hitherto
with
reported
R-CYo
affords
aldehydes
n-Pr,
an organozinc
affords
in yields
BrZnCBr(COOEt)2
(H20)
‘H
of the intermediate
in dimethoxymethane
results
condensation
reagent up to
.
52%
which not
R-CH(OH)-CBr(COOEt)2 (R=Me,
Reaction
and Ph)
28 : Cl
a-bromo-8-hydroxydiesters
+
i-Pr
product
in the formation
Et, n-Pr,
with
CC 5
acetyl
and n-Hex)
chloride
of the methoxymethyl
derivatives:
R-CH(OZnBr)--CBr(COOEt)2
Reaction
with
acetates
28 : 111
References p. 1 i2
acetyl
chloride
MeCOGl CI-$(OMe)2
in diethylether
R-CH-C
affords
Br(COOEt)2
the corresponding
J.G. NOLTES.: _-
88 MeCOCl.
R-CH-CBr(COOEt)~
R-CH-C
>
I
OZnBr
The
same
vz”
organozinc
malonates
reagent
with formatiou
below
-65O
may
esters
(IX;
yield
RCH=C
of &
be hydrolyzed 62%
for
COOEt :-
/ \
readily
‘,. ..
with diethyl
which
alkylidene-
if the temperature
to the corresponding
R=Me)
f
reacts
adduct
Br(COOEt)2
I OCOMe
is kept
o-bromotetra-
E9-j:
\
Br ZnC Br (COOEt)2
(30)
COOEt
/
RCH ’
CH(COOEt)2 C l?&OOEt)2
(IX)
At higher
temperatures
cyclization (X;
with formation
yield
59%
r
for
Russian coupling acyl
workers
of orgaiiozinc
chlorides
zinc
bromide
resulting
tetracarboxylic
in
.ester
psi:
ZnBr
CBr(COOEt)2
eliminates
of a cyclopropane
R=n-Pr)
R4I-L_(C*oEt)2
[I
the adduct
1
-ZnBr2 -
R--CH
’
1 have
,G(COOEt)2
prepared
reagents
derived
I C(COOEt),
o -substituted from
B-diketones
o-bromoketones
vi& the with
$01:
(R=Et, (R* =Me,
n-Pr, n-Pr,
n-Bu) n-Bu,
Ph)
ZINC
89 Various
derivedfrom Addition rated
synthetic
applications
a-bromonitriles
nature
of R and
69; 218) have
(AS
to benzalacetophenone
8-hydroxynitriles
of cyanomethylzinc
leads
reagents
been
reported
of Y, b-unsatu-
to the formation
(XII)
(XI) or of 64cetonitriles
@l].
depending
on the
RI:
OH PhCH=CH--&-CRR'CN &h
9
+
(XI)
PhCH=CHCPh 0-p
R’
Ph\,
i
5:
CHCH2CPh
NCCRR'
(XII)
Reaction
with
crotonaldehyde
results
R’ MeCH=CH-C/' 'H
With
diethyi alkylidene
the corresponding of 55-70s
R'
c---cN
only:
9" MeCH=CXH---CRR'CN
_ (30)
R'
malonates
diester
1,2-addition
ZnBr
\I
+
in
.exclusively
(XIII)
nitriles
having
l,&additiontakes been
isolated
place, in yields
bl]:
ZnBr \/ _C-CN
,coom f
R'UH--CH(COOEt)2
R"CH=C
R'
I 'COOEt
R--C-R'
i
a
CN
,
(XIII)
Preformed
organozinc
(AS 67; 237)addacross formation
the
reagents C=N
derivedfrom
double
in good yield of 8-aminoamides
References p. 112
bond
o-bromoamides
ofschiffbases
32 : Cl
with
I.G. NOLIE&
90 ZnBr RCH=NR'
R'KH-CONE~
i
'CH--CH(R")--CONE$
__3
@-!Z”) The
reaction
85115
B.
proceeds
of alkylzinc
-carbonand The wards
and
alkenylzinc
carbon-hetero
chemical
of such
ular of French valuable
chemists.
synthetic
Jones
and
-phenylbutanal Grignard
reagents.
istry for zinc and
prepared
four-centre
compounds
of alkyland
with carbon-
andthe
alkenylzinc
mechanistic
have
continued
This
researchhas
compounds
and
to-
stereochemical
to attract attention in particproduced
comparedthe
stereochemistry
dimethylcadmiumtowards
and
change in metal,
R"=Et).
anumber
of
procedures.
eta&have
dimethylzinc
and
:
(e.g.
atomunsaturatedbonds
reactivity
reactions
:.
R'NH'
of stereoselectivity
if R=R'=Ph
unsaturatedmolecules
aspects
Me;?Gd
with a high degree
ratio of diastereoisoners
Reactions
:
R
I
2-phenylpropanal,
2-phenyl-3-methylbutanalThe
observedtrendin of halide
the absence cadmium
from
transition
reactions,
MeLi
are
state (XIV)
of the addition
of
2-
withthatobservedfor stereoselectivity
dependence
on
the stereochem-
and the inertness
considered
with a
consistent
of with
Me2Zn
and
a bridged
p3j.
(XIV) The same
authors
chemistry
of the reaction
have
compared
the product
of in situn-propylzinc
composition and
and stereo-
icadmium
,.
reagents
_-<
ZINC
with
91
4-tert-butylcyclohexanone.
shows Cd
preference
reagents
give
two instances product
for
The
reduction
over
preferentially
gave
zinc
reagent
addition.
axial
Whereas
both
the
Zn reagents
reduction,
the non-thermodynamic
1’Zn-PrMgBr-ZnBr2”
axial
alcohol
Mg -and in
as the major
@I:
exn_pr&yH 3 1%
0
“2n-PrMgBr;
20%
ZnBr2” >
The
addition
accelerating of
of tetrabutylammonium
effect
di-n-propylzinc
tion
reaction
butanol-1 results
after
(from
complexation
the carbonyl
The reaction
resulting
a pronounced
/benzylalcohol
than with
of 9 for
and benzaldehyde
causing
indicate
pentene-2
(by a factor
and little
>I)
for
has
on the addition influence
Bu4NCl).
an
reaction
on the
reduc-
ratio
l-phenyl-
Spectroscopic
with the dialkylzinc
rather
35 . Cl
of the organozinc
in the formation
salt
(Cl>Br
in the product
to 15.6
of the
proceeds
Bu NCl) 4
change
1.3
compound
with ketones
halides
reagent
with partial
of a mixture
derived
from
allylic
of linear
l-bromo-
rearrangment
and branched
alcohols
hydrolysis:
OZnBr Et--CH=CH-C~ZnBr
f
RR’%=0
+
Et--CH=CI-GC
I
--CRR’ ‘Hz
Et
I
CI-$=ClGCH-CRR’
iReferencesp. 112
.
+
OZnBr
I
92 The
reaction
condensation
elevated
reaction
composition
been
shown
to be reversible.
and longer
temperatures
becomes.thermodynarnically
of the
thesis
has
more
stable linear
EtCH~CHC~C(OH)RR'
reaction controlled
alcohols
similar
situation applies
reagent
derived
from
applying-.
the product
enabling
the syn-
in 100%
for the condensation
l-brdmopentadiene-2,4
_-_. -;-'. '-
‘-r----
:‘..
.,.
of the type
(R=R'=Et,i-Pr,n-Bu)
A
times
By
purity
:.Y
F6-J.
of the organozinc
with aldehydes
and
ketones:
C(OH)RR'
I Cl+=CH-CH-CH=CH2
CH2=CH-CH=CH2CI$ZnBr
.
>
-I-
+
0-p)
RR’C==O
CH2=CH-CH=CH--CH2,(OH)RR' (XV)
Changing
reaction
plus 45 hrs linear
conditions
at 60°/THF
dienic alcohols.of Allylzinc
cyanoacetates
bromide
from
allows type
3 hrs
at 20°/THFto
the exclusive (XV)
undergoes
synthesis
3 hrs
at 20°
of a variety
of
ET]. conjugate
addition
with alkylidene
24: Cl
CH2=CHCH2ZnBr
-I-RCH=C
HCN WC%
‘coozt
(R=Me,Et,n-Pr,i-Pr,Ph)
Reaction
with
substituted
the ethoxymethylene
product
(XVII)
in 20%
compound yield
24 : L-l
(XVI) yields
the bis-ally1
I
ZINC
93
CI12=CHCH2ZnBr
.CN EtOCH=G’
’
CI12=CH-GH2, 3
place
(XVII)
conjugate
addition
upon interaction
in either
toluene
H
/
“=c
\
H
or
of THF
(AS
69;
224)
di-n-butylzinc
and carbonyl with
methyl
Cl +
B
“z
Zn
to produce
a-chloroacrylate
(XVIII)
COOMe
\ /
/
c=c
that the
reaction
conjugate with
addition
a second
the cyclopropane
product
molecule
(XIX)
with
Cl OZnBu
‘C’ / a
Me0
cyclization
take
AMe
H
shown
addition
38: L-1
H
It was
\COOEt
cy=cI&cq
COOEt
(XVI)
Both
,cN
CH--CH
Bu
(XVILI)
of methyl
elimination
undergoes
a
o-chloroacrylate
of n-butylzinc
chloride:
H (XVIII)
+ H’
‘C=C
/
Cl *
‘COOMe
/Cl
=I+<. \C/
GOOMe
+-
BuZnCl
/\
c5HiI
kCOOMe
(XIX)
n- Butyl(dimethy1 dition
38 . [:I
Refen?scesp_ 112
malonato)zinc
exclusively
undergoes
conjugate
ad-
J.G. NOL*:.
94
Three-membered ethylzinc NMR
chloride
ring
formation
with methyl
the product
of this
reaction
is
H
\ /
/
c=c
\
As
cis-dimethyl
(XXI).
upon interaction shown
of
.~
by IR and
1-propyl-2-chloro-
The following
reaction
scheme
.
consider.ed
H
occurs
c-chloroacrylate.
-1,2-cyclopropanedicarboxylate was
also
1391:
Cl f
EtZnCl
<
n-Pr--_C.
6 YFO
COOMe
0 ZnCl
&Me
(XX)
H
(XX)
-IH
\ /
c=c
/ \
Cl
:
ZnCl
COOMe OMe
COOMe
(-ZnC$)
>
n-Pr
-
COOMe
k4 =?z
Cl
(XXI)
The allylic
reaction
of allylzinc
rearrangment,
e.g.
reagents
with
cx-alkoxyketones
involves
40- : Cl
G2%CH=CHCH2ZnBr
C~=CK-CH(C2H5)-~C3~)(OH)-CErZOCIK
.-.
95
ZINC
o-Alkoxyesters yield. upon
afford
Pentenylzinc reaction
r
observed
reagent
with
alkoxycarbinols
diallyl-substituted
ethyl
affords
a
3/l
mixture
of (XXII)
the formation
ethoxyacetate;
in excellent and (XXIII)
of (XXIV)
is not
..
40 i .
-2
C~=CH-CH(CZHS), ,
CH(OH)C%OC&
(XXII)
C%=CH-CH(C&
CJ+=CH--CH(C&
\ ,
CZHSCH=CH-C~
CH(OH)C~OCzHg
(XXIII)
C&.CH=CH-C~, CH(OH)CI$OC2Hg
CZHSCH=CH-CH/
The
formation
reaction
of diallyl-substituted
of imino
the intermediate gested,
via
ethers formation
an isonitrile
PhNH=CHOEt
+
?
PhN=CHR
The
reaction
to otherwise amines
with
allylzinc
+
with
bromide base
Rg)
organozinc
available
RNHCRr3,
amines
e.g.
the
proceeds
as previously
via sug-
.-> -MOR
(I-$0)
PhNHCH3
compounds
symmetrically kg:
from
probably
and not,
P&N-CH-R
Y Ph-N-CH(
of isonitriles
of the type
Referencesp. 112
RM -
difficultly
secondary
of a Schiff _ . L4lj:
RM
(XXIV)
offers
substituted
a route secondary
J.G. NOLTES 1:.
96
Ph--N=C:
+
THF w
3 CH2=CHCH2ZnBr
PhNHC(C%CH=C%)3
;1
0-p (30%)
Such
compounds
reaction
may
of allylzinc
be obtained bromide
(OEt),
Ph-N=C
attractive
yields
via the
@2j:
with iminocarbonates
RM
f
in more
“: yEt
__,
Ph-&-C(R)OEt
/
6MOD)’
PIrN=C(R)OEt
+
RM
9
.
Ph-I++ (-MOEt)
PhN=CR,
Y
+
-
(RM
With
substituted
rearrangment
allylzinc stops
reagents
=
PhNHGR,
CH2=CHCH2ZnBr;
the reaction
at the iminoether
stage
which
yield
involves
61%)
allylic
@q:
,OEt PhN=C(OEt)2
Nivert
+
RCH=CHCH2ZnBr
and Miginiac
derived
from
affords
a mixture
former
strongly
have
propargylbrornide
shown
CH2=C=CHZnBr
PhN=C, (R=Me;
66%)
(R=Et;
40 ‘$11
that the organozinc
with gem-aminoethers
of the acetylenic predominate
___3 (%O)
and allenic
amines
CHRCH=C%
reagent
or with aldimines in which
the
[4g : KC= CC%CH(R)N(C,%)2
+
iV@
C4h$OCH(R)N(C
zH5)2
CI-$=C=CHCH(R)N(C,H$2
. ..I : :._.
ZINC
97
CH2=C=CHZnBr
HC= CCH2CH(C&NHR
-I-
-IF
CbHSCH=NR
An independent bases
was
tained
mixtures
obtained vation
of the reaction by Moreau
in yields
with
and secondary
of the ring occurs Whereas carbon
atom,
alifatic
carbon
H4
of
inversion
the
Ph.
et al.
opening
with
=.c-_y ‘0’
!I R, 2R)
Referencesp. 112
reagent
yield
amines
43j. c
have
:H \Me trans
as well
or with
exclusively
the highly
1-phenyl-1,2-epoxypropane
(1 S, 2 R) cis-isomer
atom
nearly
reacts
ob-
having
been
reagent
obser-
derived
aldimines
affords
reactions
of
cr-allenic
stereospecific
nature
by diallylzinc
at the benzylic reacts
also
the interesting
the corresponding
established
of configuration
the latter
made
with Schiff
authors
of the organozinc
amines,
(1 R, 2 R)trans-epoxide the
L. Miginiac
bromide
These
amines
gem-aminoethers
acetylenic
l-bromo-butyne-2
Abenhaim
44j.
the condensation
exclusively
tertiary
and allenic
up to 54%
whereas
of allenylzinc
and Gaudemar.
of acetylenic
3-bromobutyne-1
nearly the
study
reported
that
from
CH2=C=CHCH(C&)NHR
exclusively to a small
carbon
which
atom.
at the benzylic extent
at the
E5]:
Al12Zn
cyo) 3-phenylhexene-4-ol-
I(2 R, 2 S)
zmc
99 _j,
CF$=CHC~
\
MgBr
/
c=c
Ph /-
YznBr
(30) i C~=CHC~
\ Ph
/
(22%)
C=C%
C%=CHCH2ZnBr PhC=CMgBr (65%)
‘y-%3
e$_a T
C%CH=CH2 l/2
CIY-$CH=C%
.ZnBr
I 3
Ph-C-C~MgBr
\ I
With place
vinylic at 35O,
organometallic e.g.
C33CH=CHMgBr
reagents
an exothermal
.&lBr
addition
takes
@6]:
t
C%=CHCH2Zn&
c3H7, CH-CH CH2=CHCy/,
/
\
ZnBr
Mg Br
(~0) I CH2=CHC~~~(~~!)~3~7 (58%)
Referencesp. 3 I2
J_G_NOL~“‘-.;
100 C.
Carbenoid The
continued in organic The has
reactions
of organozinc
carbenoidreactivity
to attract attention and further and
organometallic
synthesis
sub.ject of carbenoid
reagents
of their
examples been
application
area
pi'].
have
dealt with synthetic
Simmons-Smith
reagent
Gem-dimethylcycloheptadienes
compounds
on the author's
applications
zinc-copper
have
of 5,5-dimethyl-Z-cyclohexanol
OWII
couple/methylene
beenpreparedvia
coupled
of the
coniodide.
cyclopropanation
with homoallylic
ring expansion
48': Ll
Zn-Cu
L480JoHBr 2.KOH/EtOH
GH21z
The
Simmons-Smith
selective
The
route
corresponding
stereoselective -bicycle
b.l.O]d
:. :
published.
of halomethylzinc
with emphasis
has
:
in this
Severalp'apers ventional
organozinc
have
reactions
beenbrieflyreviewedbyseyferth
contributions
-_ _. '.
compounds
of appropriate
-.
reaction
of cycloocten-
to anti-bi-cycle
reaction route
-1 6.l.O~nonan c
-2-01
of cis-cyclononen-3-01
(less than 0.05%
ecan-Z-01
3-01
(XXVI)
of E-epimer
i50]:
afforded (XXV)
a stereoc49]:
affords
ahighly
formed)
to anti-
101
ZINC
OH
OH
Le Perchec
and Conia
obtained bicyclopropylidene
of vinylidenecyclopropane
Templeton
Fg:
and Wie have investigated
(3o- and 3@-hydroxy, 5,6-unsaturated
the effect of IS-oxygen functions
3o- and 3S-acetoxy,
3-ethylene
acetal) of
steroids on the addition of the Simmons-Smith
to the steroidal 5,6-double bond. studied, only
via cyclopropanation
in the presence
take place with timation
Of the various
of the
3o-hydroxy
of the expected
5-cholestene
reagent derivatives
function did reaction
3cr-hydroq-5,6
a-cyclopropano-
-5o-cholestanc
Furukawa
et al. have continued
iodoalkane/diethylzinc authors
(AS 69;
Referencesp.112
225).
their investigation of the gem-di-
cyclopropanation
reagent discovered
by these
J.G.NOLTES t
102 The reagent
relative
reactivity from
generated
decrease
diethyloinc
in the order
hexene>hept-1-ene with alkyivinylethers
styrenes
(p-value
RZnCH$
(XXVII)
carbene
(ROCH=CI$)
The
effects,
the
R--in
methylene
iodide
outcome
1s - a more
same
group
/diethylzinc
tance
has
of steric in addition
of experiments suggests
nucleophilic
The
studied
with substituted
that methylene
in reactions much
of the
PhCH$-EsZn
I
carbenoid
transfer
reactionthanthat
the stereoselectivity
= 6.6 for the same
zinc carbenoid
lithium
to
by
of dichloro-
(XXVIII)
with cyclohexene
of coordination
0
Experiments
.,__,‘~~
by the phenylcarbenoidis
(syn/anti --
to
$4.
reagent
for the reaction
found
>trimethylethylene>cyclo-
(XXVII)
The
was
and&-alkenylethylethers
importance
of -1.61+0.05)
(XXVIII)
the zinc carbenoid
of decreasingnucleophilicity).
revealed
electronic
and
tetramethylethylene
(order
(RCH=CHOC&)
of olefins towards
shows 541. c
with olefins. higher
of the benzaliodide/
Thee-selectivity
in ethers
(e.g. c/anti
in diethylether)
reaction solvent
in pentane)
to the metal
shown = 17.1
than in hydrocarbons indicating atom
the impor-
c541:
>
larger=-selectivitythanthe
corresponding
103
ZINC
Interestingly
reagent
E5Zn/CI-$+2 where
the cyclopropanation
air was
is greatly
passed
shorter
yields with
as compared
atmosphere
formation
diethylzinc
experiments
-t
dominating
are
much
anitrogen
type
cyclohexene.
authors
of reaction
intermediate
These
or
route
to
d?splays and
(42%)
of EtZnCCb PhHgCC$)
and
is postulated
E-selective
as
behaviour
7-bromonorcarane
pre-
E6].
observed
reactions
vH
for the bromocyclo-
derivative
in their investigation
dichloropropylzinc
by elimination
References p. 112
of
of the fluorocyclopropane,
CHBr21
7-chloro-
of the interaction
the formation
as well
carbontetrachloride
rormation
(via PrHgCC$
and
their z-isomers
1-chloropropene with
synthetic
and/or
the preparation
zinc with polychloromethanes and
a novel
m
+
of 7-fluoro-,
over
Russian
pene
times
at a
of zinc by the interaction
A dihalogenomethylzinc
This
the endo-isomers
mediate
reaction
performedunder
offers
CHXYI
the mostusefulfor
derivative.
reaction
and
mixture
derivatives:
E5Zn
-I-
an intermediate.
(41%)
In experiments
the reaction
improved
for the chlorocyclopropane
propane
above
with trihalogenomethanes
I
was
CHCSI
by oxygen.
of halogenocarbenoids
halogenocyclopropane
CHF21
are
of olefins by the
[55j.
The
0
accelerated
into the space
rate of 10 ml/minthe
reaction
believed
carbenoid. into the
Zn-C
derivatives
isomerization
of ethyl chloride
as dichloronorcarane,
was.carried were
of dietbyl-
if the
out in the presence to proceed
Insertion bond which
of
via the inter-
of dichlorocarbene
of EsZn yield
affords
l-chloropror- 7 of ethylchlorocarbene i571: ._ -:
J.G. NOLTES
104
Seyferth
and Andrews
of halomethyl
derivatives
iodomethylzinc
iodide metal
appropriate
-t
These
works
best
iodomethyl nitrile.
may
derivative
involve
paper
a two-step
(AS 65;
n-Bu$iH
46)
n-B
Y
Furukawa and organotin
ethylidene
38
et al. hydrides
(cf.
3
metal
prepared
bromide
SiCHI
from
by the
and of the in aceto-
of the
bond in organosilanes
or reduction-alkylation
The
exclusive
the reaction
of IC%ZnI
formation
of a mixture
shows
of
of E
that the direct
s
SiD
insertion
58 . c1 have
investigated
with the
AS 65;
the reaction
E?Zn/RC% reacts
reagent.
with insertion
46) :
EtZZn/RCHs RzR3SiH
chloride
that interaction
ZnClI
The procedure
by the reaction
or silver
alkylation-reduction eliminated.
attack
+
bromomethyl
with the silicon-hydrogen
was
of
with the
Me,SnC%I
center.
corresponding
the possibility
of triorganosilanes group
in THF
nucleophilic
heavy
best
silver
with an excess
is operative
in a variety
are
with
reagent
E5SiCE_LLD and
process
The
synthesis
e.g.
Me$nCl
as involving
at the electrophilic
In the same
sequence
and
pictured
compounds
Simmons-Smith
halide,
of their
via the reaction
bromide
IICHZ ZnI L -
C?I-transfer.
chloromethyltin
the details
and mercury
1
THF -*
are
for
lead
of tin,
or organometallic
reagent
XC%ZnX
published
or bromomethylzinc
Zn-Cu
reactions
have
p
R1R2R3SiCyR (R=H
or Me)
of organosilicon The Si-H
bond
of a methylene
or
:
105
ZINC However,
iodide
in the reaction by the organotin
methylene
group
oftriethyltin
hydride
into the
reactivities
of substituted
noid yielded
a
and
insertion,
ethylene
-1.31
p-value
(AS 69;
both
reactions
predominates
Sn-H
over
Hammet
bond.
of -1.11 LO.03
and
methylene
suggesting
correlations towards
of the
of relative
the zinc
-1.19tO.05
insertion
a similar
of the organic
the insertion
as compared
respectively,
259)
reduction
aryldimethylsilanes
for the corresponding
mercury
hydride
carbe-
for methylene
witha
p-value
of
via bis(bromomethyl)-
transition
state (XXIX)
for
59J: C' Me
/\ cl-
I 6f Si
--------H
I’\
X-
:’
'\ 6-t' ;C+lR I \ / \ . \ z.:______:y
Z=XZn,
R=H,
Z=XZn,
R=Me,
Y=I Y=I
Me
Z=HgCI-$Br,
R=H,
Y=Br
~XXIX)
III. ORGANOZINC Several organozinc Abstracts
COMPOUNDS papers
providing
compounds of patent
AS
POLYMERIZATION
details
on the catalytic
in polymerization applications
and
reactions
patents
catalysts
pounds
of the catalytic
appeared
such
has
system
Referencesp.112
Abstracts,
presentedan
polymerizations
as brought
catalyst
components
in Chemical
Kuntz epoxide
of the
about
with
will not
excellent emphasis
by zinc-containing
di-isobutylaluminium
properties
have
describing
multi-component polymerization as one
CATALYSTS
containing
of
appeared. a variety
organozinc
system,
which
of comhave
be surveyedhere.
survey
of the mechanism
on coordinative
of
polymerizations
initiator systems
bo].
The
acetylacetonate/diethylzinc/water
J.G. NOLTES
106
was
found
zation The
to be particularly
of propylene
maximum
water
bonds
revealed
l$Al khich
groups
present
and that the vn
compound
as
shown
‘Zn
The
zinc
atom
and aluminium
may
type,
was
both
study
at a maximum
that the active
Al-O-Al
coordinated
for
and
has the cata-
R-Al
to the Al-O-Al
64:
/R
play
a major
FO,
is
A kinetic
speculated
requires
component
in (XXX)
R
It was
of
with all the metal-
components. rate
61 . CJ
when the amount
to react
polymerization
of the living
the copolymeri-
and allylgiycidylether
required
%O/F$Zn.
about
is observed
in the catalyst
acac /0.5 is
to polymer
than that
that the initial
system lyst,
is less
in bringing
epichlorohydrin
oxide,
conversion
present
-carbon
effective
a major role
role
in polymer
in epoxide chain
monomer
growth
coordination
[60]:
OCHCI$OCHC%OR
107
ZINC
-?2 =:
c
rH3
/ ,O,,
,0CHCF~OCHCX~OCHCH20R
2'zh /
Recent have
d
'. ..,??I
from
papers
clarified
several
dialkylzinc
catalyst
Et2Zn/H20
system
systems.
presence
of both
62. Cl
kinetics
The
The
Zn-0
and
of the
Zn-Et
diethylzinc/water
metric
polymerization
active
polymer
Tsuruta
active
pound:
the polymerization
the antipode
resulted
monomer
in restoration
of catalyst
-stereoselective.
If, however,
to the deactivated
catalyst,
tivitywas
regenerated
of styrene
oxide
/(-)-menthol Referencesp. 112
has
k5].
Fj. been
effected
asymmetric with
been
with
com-
poly-propylene
oxide
following
addition was
dialkylzinc asymmetric
selection
the catalyst
brought
(+)-bis(2-methyl-
but the catalyst
catalyst
by
acids
dialkylzinc
with
active
Asym-
realized
L-o-amino
of diethylzinc
the optically
The
earlier
active
the
of an optically
by the further
activity,
an active
E3]. 2
active
Addition
catalyst
discussed
69; 227) has
oxide
species
using
with
(AS
optically
63. C
of the asymmetric
deactivation
compounds
an optically
afforded
catalyst
(formation
of DL-propylene
catalyst
been
the
oxide
mixture)
as cocatalysts
et al. by using
butyl)zinc/water
leaving
dialkylzinc
alcohols
by Furukawa
monomer
is im-
activity requires
of propylene
(l/2) has
of the
oxide
in the active
of epoxides
a racemic
et al. by using
or optically about
from
catalyst
bonds
initiated by
reproducibility
of propylene
polymerization
initiator system selection
catalytic
Et2Zn;
University
polymerizations
for the polymerization of free
at Kyoto
of Furukawa
of epoxide
aspects
by the removal
proved
the group
etc.
of water nonwas
added
selec-
polymerization
system
diethylzinc/
J.G.NOLTES:.
.108
Sakata
CY, $-unsaturatedketone propylene
catalyst
-dimethylacrylophenone
Conjugate gives
of EsZn
addition
a catalyst
were
and
Tsuruta
fruitful studies
dealing
the area
of carbon EtzZn/%O unitinthe following both cases trans
at Tokyo
wit__ '-the application catalysis.
with
polycarbonate alkaline the
showing
system
bil.
hydrolysis
or
in the ring opening
is
configuration
r7 1_66J-
was
of the
specifically inverted
their in
is their
copolymerization
(EPCH)using
-reduction
1,2-cyclohexanediolformed that the
ineffective.
interest
alternate
(cis ortrans) --
LiAlH4
other
compounds
of
Th e configuration
. _
@,B-
(AS 69; 224)
of organozinc
Of particular of the
copolymer
and
were
continued
have
cis-1,2-epoxycyclohexane
(l/l) catalyst
of
stability at high temperature
University
of the stereochemistry
dioxide
acrylophenone
or methylacrylate)
activity and
of polymerization
investigation
for the polymerization
to cu,@-u&aturatedketones
with better
of diethylzinc/
but carbonylcompounds
suitable,
2-furylacroleine
(e.g.
Inoue
systems
$!I<3. Methilisopropenylketone; .. -
oxide
than ketones
the effectiveness
demonstrated
et al. have
was
a the
EPCH
determined
of the copolymer.
In
found to be exclusively
EPCH
carbon
atom
involved
during
the copolymerization
k7: LI
Et2Zn/J+0 f
Hydrolysis
nCO2
of poly-(propylene
polymerization
carbonate)
of R-(+)-propylene
oxide
obtained
by alternating
with carbon
dioxide
co-
using
a
I E%Zn&O
catalyst,
tollowed
resultedintransformation propylene
by treatment
of the epoxide
glycolbis-p-nitrobenzoate.
with p-nitrobenzyl unit of the copolymer
Determination
chloride, into
of the optical
109
ZINC
activity
of this
asymmetric fore,
ester
revealed
carbon
atom
of the epoxide
the organozinc-catalyzed
at the
methylene-oxygen Kawakemi
ring
linkage
and Tsuruta
or methyl
Methyl
in toluene,
type
catalyst
with
methyl
zation
or .THF,
68 . II
activity
n-
for
acrylate
carried
using
n-Bu;!Zn
results
studies
pj. with
or
n-butyl-
of the copolymeri-
indicate
but in HMPT
out
(HMPT)
or copolymerized
The
as kinetic
of diethylzinc system
place
as a third
allowed
methacrylate.
takes
obtained
a radical-type
an anionic
mechanism
cocatalyst
the block Under
and products
copolymerization
certain with
in a Ziegler-Natta
conditions
controlled
of ethylene no homopolymeri-
composition
could
be
[69].
The
valence
polymerize
state
propylene
relationship
or the molecular
A.
as well
mechanism
was
triamide
solution
as a catallyst.
predominantly
of methyl
the polymerization
or HMPT
in toluene
The use
served
catalytic
There-
38 . Cl
applies
direct
place
an anionic
can be polymerized THF
experiments
polymerization
takes
a low
of the
copolymerization.
or hexamethylphosphoric
(dimethylmalonato)zinc zation
indicating
provided
o-chloroacrylate
styrene
opening
configuration
in the polymerization
methacrylate
in dimethylsulfoxide
of the
upon
observed
-butyl(dimethylmalonato)zinc
IV.
the inversion
of titanium
in the
to isotactic
between weight
the
EsZn/TiC13
polymer Ti
2f
or isatacticities
has
content
been
and the
catalyst
used
investigated. catalyst
of the polymers
was
A
activity not ob-
70 . Cl
STRUCTURAL,
Structural An X-ray
Referencesp. 112
SPECTROSCOPIC
AND
PHYSICAL
STUDIES
studies crystal
structure
determination
of the anionic
zinc..-
to
J.G. NOLTES
110 -borane
complex
-decarborato)zincate The
structure
ligands
kSMeP]2
can be considered
Fig. 1. Structure boron
(Af, 1971,
The
only cfrom
been
reported
two bidentate
to zinc (Fig-
EloHlzZ-
1).
s h owing
N.N.Greenwood
[7q.
the positions
etal.,
of the
J.Chem.Soc.
Skj.
studies
IR and
Raman
spectra
methylzincate
7L$Zn(C3)4,
reported.
spectra
2n-C
has
to comprise
of i;'~MeI$~n(B10H12)2]
atoms
B. Spectroscopic
band
kn(BloH12)d
co-ordinatedtetrahedrally
zinc and
bis(dodecahydro-nido-.
methyltriphenylphosphonium
The
at 520 cm
-1
stretching
of the isotopic
6 L5Zn(CH-$+
indicate
Td
in the IR spectrum mode
bill.
symmetry
analogs
and
of lithiumtetra-
7L$Zn(Cnj)4
around
of 'Li2Zn(CD,),
the zinc
been
have atom.
isassigned
A
to the
111
ZINC A iodide
PMR in THF
solution
alkyl exchange PMRtime
(corresponding
to the
Oliver
et al. have
of
ZnI2
in going
of
borate(2-1 Travers
the
anionic
ion
groups
and
for changes
kinetic
solvent
equi-
AS
28.87
*
MHz
on the rate and dimethylzincparameters
are of the
(dichloromethane,
solvent
eu) to a strongly
(diethylether,
coordinating
solvent
= + 2 eu). and
80.53
MHz
llB-NMR
of the dodecahydro-nido-deca-
complex
were
of zinc iodide)
in the mechanism
coordinating
has
~e4Nj2[Zn(BloH12)21
[7] and the results
on the
1.00/1.05
the Schlenk
in the system
energies
of the
zinc
amount
effects of solvent
a non-coordinating
discussion
is slow
(R=Me,Et)
the
AS #= z-14
173j. At -70°
ratio was
that
ethylzinc
500 at -9OO):
Ea f' = 16.3 kcal/mole;
A detailed spectra
studied
to a "weakly"
(triethylamine,
Zn/i
with a small
2RZnI
is presented
9 ..1 kcal/mole.
the
and
et al.
diaikylzinc
confirming
Activation
from
and
in which
of methyl
.- ? p41.
< 5 kcal/mole)
Ea '=
0
for methyl-
by Evans
iodide
right (K>
exchange
Evidence
reaction
reported
observedat-90°
+
trimethylindium
Ea
solutions
52Zn
reported.
been
to "alkylzinc.iodide"
line was
mechanism
equilibrium
alkylzinc
For
lies well
librium
has
between
scale.
only one
of the Schlenk
study
been
correlated
presented with
by Greenwood
the known
and
structure
L711 in the solid state. t-Butoxy in
radicals
the presence
tion at the cavity t-BuO=
metal
of diethylzinc centre.
the E.S.R. +
Et2Zn
Referencesp.112
generated
induce
of di-t-butyl.peroxide
an homolytic
If the reaction
spectrum -+
by photolysis
is carried
bimolecular.
out in an E.S.R.
of the ethyl radicaicanbe EtZnO-t-Bu
-I- Et.
substitu-
observed
75 : [I
J.G.EiOLTEs..’ :
112
C.
Other
physical
Complex with
studies
formation
2,2’-bipyridine,
ethylene
ethylene
diamine
stoechiometry
(CH_&Zn,
of
has
been
diamine
studied
and dissociation
agreement
with earlier
(C21-I$2Zn and
(iso-C3I-&-Zn
N,N,N*,N’-tetramethyl-
by an oscillometric
constant
results
and
method.
of the complexes
(AS 67; 235)
The
were
in
fi61. -3
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117
LG. NOLTES 75.
A. G. Davies, 1971,
76.
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So+
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1823
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Abstr.,
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Acta 46216
Chim. 3
(Budapest),
66
ZINC ANNUAL
SURVEY
COVERING
THE
YEAR
1971
Utrecht
(The
Jan G. Nolte s Organis
ch Chemis
ch Instituut
TNO,
Netherlands)
CONTENTS
I.
Preparation
II.
Reactions
of organozinc
of organozinc
A.
Reformatsky
B.
Reactions -carbon
C.
reaction
and related
reactions
Organozinc
compounds
IV.
Structural,
spectroscopic
A.
Structural
B.
Spectroscopic
C.
Other
atom
82
reactions
and alkenylzinc
and carbon-hetero
III.
82
compo?mds
of alkylzinc
Carbenoid
77
compounds
compounds
unsaturated
of organozinc
with
carbon-
bonds
90
compounds
as polymerization
and physical
100
catalysts
105
studies
109 109
studies
110
studies
physical
studies
112
References
I.
112
PREPARATION The
new
1971
organozinc
Referencesp. 112
OF
ORGANOZINC
literature compounds
contains
COMPOUNDS relatively
or new types
few
references
of organozinc
dealing
complexes.
with
78
J.G.NOL~ Lorberth
metal
has published
derivatives
acidolysis
the details of his synthesis Such
of diazoalkanes.
of the very
with diazomethane
reactive
compounds
were
bis(trimethylsilylamino)
or ethyldiaeoacetate
of Group
:.._'-
II B
_~
obtainedby derivatives
LlJ: I
Zn:N(SiMe3)
?!I
ZniN(SiMy)2d2
2
.:
+
CH$$
g%+
+
2HC(N$OOEt
,bnCN2],
%!%
+
. .
ZHN(Si&),
Zn[C(N2)COOEq2
f
+
ZHN(SiMe) 32
Noveltrinuclear characterized spontaneous
by Bdersma
+
n acac'
1
of the
benzene
Hacac
+
S-diketonate
et al. Complexes
disproportionation
P$Zn
2phZ
phenylzinc
P
Ph2Zn
oftype
t
have
been
(I) are formed
Ph2Zn/S-diketone
iPhZnaca4.
f
complexes
via
l/l reaction
PhH
Zn(acac)2
i’
2 :FhZnacaci ‘L +
Zn(acac)2
_3
'PhZnacac]2. !_
Zn(acac)2
(I)
product mixed
or by a stoechiometric
reaction
which
allows
the isolation of
complexes:
.
2PhZnpac
+
Zn(acac)2
w
[PhZn pad 2. Zn(acac)2
-_.
79
ZINC For
(I) a structure
coordinate
terminal
Kawakami weight,
and
e.g.
data)
+
shown
carbonyl
using
f
been
reported
as well
zinc
proposed
of the products
(BuZ2.n
Aminophosphine
P%Zn
have
C%(GOOMe)2
were
o, g-unsaturated
synthesized
has
central [
a study formed
as
-dimethylsilane
b
to undergo compounds
derivatives
BuZnX)
(analytical,
molecular
with active
RNHPP%
%%
MeOZnCH(COOMe)2
a Michael-type
of
methylene
l/l acts
atom
of dimethyl-
baur
and Wolfsberger
complexes as
a
reaction
in which
and diethylzinc
BuH
1,4-addition
compounds
with
have
been
4 -
rJ-
PhZnNRPP%
1,3-bidentate
+
i-31=
of organozinc
an acidolysis-type
zinc
Referencesp. 112
Zj.
by the interaction
f
(R = 2,3-Me&,?,
Crystalline
and two tetra-
:
BuZnOMe
products
atoms
Tsuruta
compounds
compounds,
one hexacoordinate
zinc
IR and NMR
n-butylzinc
Such
with
PhH 4-MeC6H4,
2-pyridyl)
bis-trimethylphosphinimoligand
have
to the tetracoordinate
been
reported
by Schmid-
-80
Me
%
Zn
+
/
M?P=N
(Me,P=N),BiMe2
R
Various
reports
hydridozinc
complexes
Tsuruta wards
carbon
rated
dealing
ketones
et al.
have have
\
‘Zn’ 11
N=PMe3
R
of anionic
the synthesis
and a variety
of saturated
tetra-n-butyl
and Travers
have
and reactivity
CaZn(nkBu)4
reported
anionic
zinc,
of the dodecahydro-nido-decaborate(2-)
[7].
complexes
which
obtained
by ionization
2 ZnB10H12-2
yields
reaction
a compound
2CH3ZnI
isolated
+
3NaH
in water
results
Et20
of the neutral
is a bis-ether
%%
of methylzinc
+
ion
salts
compound
are
which
readily according
complex:
ZnZf
+
iodide
of the composition
cadmium
as the bis-(trimethyl-
or the bis-(methyltriphenylphosphonium)
to new analytical
The
were
to-
[61. _
complexes
ammonium)
or
and o, @-mnsatu-
and mercury Th e zinc
alkylzinc
appeared.
of calciumzinc
Greenwood
Bi’
with the synthesis
investigated
tetrachloride
Me
Zn(B10H12)‘-
with
sodium
NaZn2(GH3)2%
NaZn2(C’H3)2H3
f
+
hydride for
4 Et20
in THF
which
the
2NaI
(11) following
structures
were
considered
kj
_. H “3-Z++,
‘‘;r n-C%
H
: I_.*. .
ZINC
81
J
Reductions with
with this
reductions
LiAlH4,
precursor high
hydride
converts
NaZnH3
The and
Beach
has
NaZnE$:
zinc
or
THF
4KH
2KZn(sec-Bu)3
diethylether
diethylether reaction
Referencesp. 112
of potassium
2
+
to
f
stability
than
been
hydride
(II) is a
heating
(CI-$),Zn
has
%nH2 I8 _ -‘.
obtained
with
under
xTHF
by Ashby
di-sec.butylzinc
of the anionic
K2ZnH4
-
the
is
quite
reaction
complex
2 KZn(sec-Bu)3
+
Zn
thermally
of zinc
as a route
of the thermal energy
+
K,ZnH4
unsuitable
an activation p 11.
-
K2ZnH4
found
at -45-50° study
Zn
3 l5
ZnH2
authors
a kinetic
thermal
K2ZnH4
facile.
Moderate
+
obtained
[S ,: _ i
-I- 3 (see-Bu)
Russian
of zinc.
and by the hydrogenation
in THF
In contrast
greater
to those
particularly
NaZnH3
hydride
by the reaction
KZn(sec-Bu)3
this
(II) into
somewhat
quaternary
in benzene
From
hydride
4
similar
being
ternary
THF
N~Zn(C~),~.x
results
of nitriles
to the first
vacuum
afford
of 27.9
Kcal/mole
6 C4H10
stable
iodide
to zinc
decomposition
+
with
hydride of-zinc was
[9j.
LiAlH4
in
$Oj_ hydride
obtained
in for
82
J-G_ NOLTE$
II.
REACTIONS
A.
Reformatsky The
remained
this
research,
past
reaction
year
of functionally
which
has
new
and related aspects
have
perature
in benzene
observed
that
vent
procedure
containing
8-hydroxy
allows
conditions,
e.g.
dilute HCl
BrZnC%C
Ph\
Stereo-
Rathke
at room
yields
may
be obtained
when the carbonyl l2 13
o-bromoesters of
The
and,
compound
/ \
of this
is’especially
. of alkyl
8-hydroxyacids. under
o-
The primary
extremely
mild
-0 OSi Me3
C(OH)C%COOH
carbaethoxymethyl
reaction group
has
(80%)
been
applied
in organosilicon
more
when a sol-
advantage
instead
hydrolyzed
tem-
and Lindert
temperature
is used,
synthesis
at reflux
Et/
The Reformatsky of the
In the
:r 3]: i.
+
_
In
chemists,
in the literature.
conducted
condensation
0 Ph-&-Et
of French
emphasized.
solvents.
trimethylborate
are
research.
attention.
readily
esters
reagents
of the Reformatsky
is normally
quantitative
a facile
trimethylsilyl
are
appeared
received
of trimethylsilyl
dbromoesters
the domain
applications
proceeds
apparent
organozinc
of organozinc
aspects
have
to base-catalyzed
The use
largely
synthetic
also
area
or benzene-ether
reaction
is most
susceptible
been
reaction
that nearly
mixture
active
reactions
The Reformatsky
important,
most
reactions substituted
than organometallic
numerous
chemical
COMPOUNDS
and related
the single
rather
reaction
ORGANOZINC
sllemistry
has
organic
OF
for
the introduction
k4],
organogerma-
..
ZINC
83
c-*
niUm
151 and
'?MX
organotin
+
E.g.
is used
compounds:
3
ZnBrCH2COOEt
Nitrones furan
$4
maybe
--+
appliedas
as the solvent
carbonyl
and
+
analogs
ZnBrX
whentetrahydro-
the reaction
temperature
react
zinc and
N-methyl-C-arylaldonitrones
to yield the corresponding
$MCH;?COOEt
with
is controlled, o-bromoesters
2-methyl-3-aryl-5-isoxazolidones
(III) '>6-: _ 2
\c//p \ /I
i
OEt
jN\ Me
OZnBr
/--
>
kjLc_&;, /
-BrZnOEt
\ c=o
MeANlO/ (III)
Several sation
reactions Luche
reaction nearly
studies
and
have
with
dealt with
Reformatsky
Kagan
have
with Schiff bases. quantitative
formation
(IV). At refluxtemperature formed
as well.
degree
of.reversibility
References p. 112
The
investigated The
the stereochemistry
preformed
of aminoesters
were
of conden-
reagents.
a certain
results
stereochemicalaspects
amount
reagents with
at -18O
react
with
erythro-configuration
ofthreo-isomer
interpretedinterms
for the condensation
of the
reaction
(V) is
of a certain . 17 :
11
.c
LG. NOLT+:-
84 ZnBr
I;I I ’
7
Phb&N-Ph
0
RCH-C” +.
I R----C-GOOR’
PhCH=N-Ph
-COOR’
A
H
I;.
(VI
(IV)
A_ stud?
of the stereochemistry
to Z-methylequatorial the order
ZnBr
1 Ph&-A--Ph
‘OR’
+ +-
I Rrr,&
sf
I
nBr
of addition
and 2-ethylcyclohexanone attack
the ratio
of 4jl
revealed
of Reformatsky a strong
to cis-epimeric
of -trans-
reagents
preference
alcohols
for
being
in
E8]:
f
.aR
0
BrZnCEI2C~
‘OR’
CL
w
, OH tE$COORl
This
is the trend
type
of addition
generally
coworkers
product
a .
threo-
compounds
H
* *
s
H
erythro-
derived
rapidly
(650/d isomers
-6
11.
that in DMSO
reagent
Ph
Ph--6-A--COOMe BrZnO
shown
and benzaldehyde
(35%).and
H
have
of the Reformatski
-bromophenylacetate of erythro-
by alkylzinc
for
this
(AS 69; 2231.
Blagoev-and densation
followed
from
equilibrates
$9j:
H
.
, I
Ph--C-C-COOMe Bri%O
at 45O the con-
A Ph A
threo-
methyl
o-
to a mixture
ZINC
The
85
same
authors
ary butylgroup (erythro/threo DMSO
that
observed
slightly favors the formation = 48/52)
at -5Othe
bi].
condensation
the Reformatsky
of the methyl
replacement
Gaudemar
of the erythro-isomer
et al. have shownthatin
of benzaldehyde
reagent derived from
by aterti-
or acetophenone
ethyl or propyl
with
o-bromobutyrate
is kinetically controlled [21]. The asymmetric reagents
has
been
realized
tion in an asymmetric mine) has made
synthesis of 8-hydroxyesters by carrying
which
Reformatsky
possible the synthesis of p-hydroxyester
reagent
as high as 98%.
was
dia-
with (S) con-
Application of the
in dimethoxymethaneincreasedthe
on the substituentgroups
depending
condensa-
solvent. The use of (-)spartein (a tertiary
figuration having optical purities preformed
out the
using achiral
opticalpur ity
in the order
of 35-98s
t22j. Reformatsky
reagents
undergo
with diethyl alkylidene malonates, yields of 52&O%
conjugate addition upon interaction 1,4-adducts
having beenisolatedin
k3]:
/ EtooCC?R’ CH---CH R'
A similar
1,4_additiontakes
allowing the preparation
Referencesp. 112
\
COOEt
COOEt
place with alkylidene cyanoacetates
in 50-60 yield of o-cyanoglutaric
esters
;241:
J.G. NOLTES
86
CH H R
\ /
CN
/
c=c
C
\
0
//
BrZnCH2C
\
COOEX
R--CH--CH IqzJ-+
1
halogen
bonds.
derived
from
C~-eooEt
been
undergo
A complete
reported
developed
reagents
ethyl
-.
‘Cody
Ol3
(R= Et, n-Pr,
Reformatsky
product
coupling study
o-bromobutyrate
and conditions
reactions
with
of the reaction
obtaining
(VI)
-.
i-Pr)
carbon
of the reagent
with bis(chloromethyl)ether
for
.’ :-. :
/
in 5545%
has
yield
were
p51:
2
K1=y20
The
synthesis
I?-60%
has
been
matsky
reagents
of esters effected
with
of substituted
by Russian
a-ketoesters
( EtOe+G%-!20
(r,ou
malic
workers
acids
via
in yields
condensation
of of Refor-
$26 :
1
0 Ph:COOR
+
BrZnCHR’COOR
PhC(OH)(COOR)CHR’COOR W (R=Me,
Several substituted matsky
papers organozinc
reagents Methyl
undergoes
have
dealing
compounds
synthetic differing
applications from
R’=H,
Me, Et)
of functionally
the traditional
Refor-
appeared.
Q’-bromocrotonate
conjugate
with
Et;
addition
affords
an organozinc
with diethyl
alkylidene
reagent malonates.
which A mix-
..
87
ZINC ture
of the products
ment)
(VII;
straight
addition)
and
(VIII;
allylic
rearrang-
is isolated
COOEt R-CH=C
/ \
+
BrZnCl-$-CH=CH~OOMe
COOEX
R-CH-CH(COOEt)2 7qF
R--CH-CH(COOEt)2
kH+H=CH--COOMe
I
+
CH2=CH-CH400Me
(VII)
(VIII) fR=Et,
Diethyl upon
dibromomalonate
condensation
hitherto
with
reported
R-CYo
affords
aldehydes
n-Pr,
an organozinc
affords
in yields
BrZnCBr(COOEt)2
(H20)
‘H
of the intermediate
in dimethoxymethane
results
condensation
reagent up to
.
52%
which not
R-CH(OH)-CBr(COOEt)2 (R=Me,
Reaction
and Ph)
28 : Cl
a-bromo-8-hydroxydiesters
+
i-Pr
product
in the formation
Et, n-Pr,
with
CC 5
acetyl
and n-Hex)
chloride
of the methoxymethyl
derivatives:
R-CH(OZnBr)--CBr(COOEt)2
Reaction
with
acetates
28 : 111
References p. 1 i2
acetyl
chloride
MeCOGl CI-$(OMe)2
in diethylether
R-CH-C
affords
Br(COOEt)2
the corresponding
J.G. NOLTES.: _-
88 MeCOCl.
R-CH-CBr(COOEt)~
R-CH-C
>
I
OZnBr
The
same
vz”
organozinc
malonates
reagent
with formatiou
below
-65O
may
esters
(IX;
yield
RCH=C
of &
be hydrolyzed 62%
for
COOEt :-
/ \
readily
‘,. ..
with diethyl
which
alkylidene-
if the temperature
to the corresponding
R=Me)
f
reacts
adduct
Br(COOEt)2
I OCOMe
is kept
o-bromotetra-
E9-j:
\
Br ZnC Br (COOEt)2
(30)
COOEt
/
RCH ’
CH(COOEt)2 C l?&OOEt)2
(IX)
At higher
temperatures
cyclization (X;
with formation
yield
59%
r
for
Russian coupling acyl
workers
of orgaiiozinc
chlorides
zinc
bromide
resulting
tetracarboxylic
in
.ester
psi:
ZnBr
CBr(COOEt)2
eliminates
of a cyclopropane
R=n-Pr)
R4I-L_(C*oEt)2
[I
the adduct
1
-ZnBr2 -
R--CH
’
1 have
,G(COOEt)2
prepared
reagents
derived
I C(COOEt),
o -substituted from
B-diketones
o-bromoketones
vi& the with
$01:
(R=Et, (R* =Me,
n-Pr, n-Pr,
n-Bu) n-Bu,
Ph)
ZINC
89 Various
derivedfrom Addition rated
synthetic
applications
a-bromonitriles
nature
of R and
69; 218) have
(AS
to benzalacetophenone
8-hydroxynitriles
of cyanomethylzinc
leads
reagents
been
reported
of Y, b-unsatu-
to the formation
(XII)
(XI) or of 64cetonitriles
@l].
depending
on the
RI:
OH PhCH=CH--&-CRR'CN &h
9
+
(XI)
PhCH=CHCPh 0-p
R’
Ph\,
i
5:
CHCH2CPh
NCCRR'
(XII)
Reaction
with
crotonaldehyde
results
R’ MeCH=CH-C/' 'H
With
diethyi alkylidene
the corresponding of 55-70s
R'
c---cN
only:
9" MeCH=CXH---CRR'CN
_ (30)
R'
malonates
diester
1,2-addition
ZnBr
\I
+
in
.exclusively
(XIII)
nitriles
having
l,&additiontakes been
isolated
place, in yields
bl]:
ZnBr \/ _C-CN
,coom f
R'UH--CH(COOEt)2
R"CH=C
R'
I 'COOEt
R--C-R'
i
a
CN
,
(XIII)
Preformed
organozinc
(AS 67; 237)addacross formation
the
reagents C=N
derivedfrom
double
in good yield of 8-aminoamides
References p. 112
bond
o-bromoamides
ofschiffbases
32 : Cl
with
I.G. NOLIE&
90 ZnBr RCH=NR'
R'KH-CONE~
i
'CH--CH(R")--CONE$
__3
@-!Z”) The
reaction
85115
B.
proceeds
of alkylzinc
-carbonand The wards
and
alkenylzinc
carbon-hetero
chemical
of such
ular of French valuable
chemists.
synthetic
Jones
and
-phenylbutanal Grignard
reagents.
istry for zinc and
prepared
four-centre
compounds
of alkyland
with carbon-
andthe
alkenylzinc
mechanistic
have
continued
This
researchhas
compounds
and
to-
stereochemical
to attract attention in particproduced
comparedthe
stereochemistry
dimethylcadmiumtowards
and
change in metal,
R"=Et).
anumber
of
procedures.
eta&have
dimethylzinc
and
:
(e.g.
atomunsaturatedbonds
reactivity
reactions
:.
R'NH'
of stereoselectivity
if R=R'=Ph
unsaturatedmolecules
aspects
Me;?Gd
with a high degree
ratio of diastereoisoners
Reactions
:
R
I
2-phenylpropanal,
2-phenyl-3-methylbutanalThe
observedtrendin of halide
the absence cadmium
from
transition
reactions,
MeLi
are
state (XIV)
of the addition
of
2-
withthatobservedfor stereoselectivity
dependence
on
the stereochem-
and the inertness
considered
with a
consistent
of with
Me2Zn
and
a bridged
p3j.
(XIV) The same
authors
chemistry
of the reaction
have
compared
the product
of in situn-propylzinc
composition and
and stereo-
icadmium
,.
reagents
_-<
ZINC
with
91
4-tert-butylcyclohexanone.
shows Cd
preference
reagents
give
two instances product
for
The
reduction
over
preferentially
gave
zinc
reagent
addition.
axial
Whereas
both
the
Zn reagents
reduction,
the non-thermodynamic
1’Zn-PrMgBr-ZnBr2”
axial
alcohol
Mg -and in
as the major
@I:
exn_pr&yH 3 1%
0
“2n-PrMgBr;
20%
ZnBr2” >
The
addition
accelerating of
of tetrabutylammonium
effect
di-n-propylzinc
tion
reaction
butanol-1 results
after
(from
complexation
the carbonyl
The reaction
resulting
a pronounced
/benzylalcohol
than with
of 9 for
and benzaldehyde
causing
indicate
pentene-2
(by a factor
and little
>I)
for
has
on the addition influence
Bu4NCl).
an
reaction
on the
reduc-
ratio
l-phenyl-
Spectroscopic
with the dialkylzinc
rather
35 . Cl
of the organozinc
in the formation
salt
(Cl>Br
in the product
to 15.6
of the
proceeds
Bu NCl) 4
change
1.3
compound
with ketones
halides
reagent
with partial
of a mixture
derived
from
allylic
of linear
l-bromo-
rearrangment
and branched
alcohols
hydrolysis:
OZnBr Et--CH=CH-C~ZnBr
f
RR’%=0
+
Et--CH=CI-GC
I
--CRR’ ‘Hz
Et
I
CI-$=ClGCH-CRR’
iReferencesp. 112
.
+
OZnBr
I
92 The
reaction
condensation
elevated
reaction
composition
been
shown
to be reversible.
and longer
temperatures
becomes.thermodynarnically
of the
thesis
has
more
stable linear
EtCH~CHC~C(OH)RR'
reaction controlled
alcohols
similar
situation applies
reagent
derived
from
applying-.
the product
enabling
the syn-
in 100%
for the condensation
l-brdmopentadiene-2,4
_-_. -;-'. '-
‘-r----
:‘..
.,.
of the type
(R=R'=Et,i-Pr,n-Bu)
A
times
By
purity
:.Y
F6-J.
of the organozinc
with aldehydes
and
ketones:
C(OH)RR'
I Cl+=CH-CH-CH=CH2
CH2=CH-CH=CH2CI$ZnBr
.
>
-I-
+
0-p)
RR’C==O
CH2=CH-CH=CH--CH2,(OH)RR' (XV)
Changing
reaction
plus 45 hrs linear
conditions
at 60°/THF
dienic alcohols.of Allylzinc
cyanoacetates
bromide
from
allows type
3 hrs
at 20°/THFto
the exclusive (XV)
undergoes
synthesis
3 hrs
at 20°
of a variety
of
ET]. conjugate
addition
with alkylidene
24: Cl
CH2=CHCH2ZnBr
-I-RCH=C
HCN WC%
‘coozt
(R=Me,Et,n-Pr,i-Pr,Ph)
Reaction
with
substituted
the ethoxymethylene
product
(XVII)
in 20%
compound yield
24 : L-l
(XVI) yields
the bis-ally1
I
ZINC
93
CI12=CHCH2ZnBr
.CN EtOCH=G’
’
CI12=CH-GH2, 3
place
(XVII)
conjugate
addition
upon interaction
in either
toluene
H
/
“=c
\
H
or
of THF
(AS
69;
224)
di-n-butylzinc
and carbonyl with
methyl
Cl +
B
“z
Zn
to produce
a-chloroacrylate
(XVIII)
COOMe
\ /
/
c=c
that the
reaction
conjugate with
addition
a second
the cyclopropane
product
molecule
(XIX)
with
Cl OZnBu
‘C’ / a
Me0
cyclization
take
AMe
H
shown
addition
38: L-1
H
It was
\COOEt
cy=cI&cq
COOEt
(XVI)
Both
,cN
CH--CH
Bu
(XVILI)
of methyl
elimination
undergoes
a
o-chloroacrylate
of n-butylzinc
chloride:
H (XVIII)
+ H’
‘C=C
/
Cl *
‘COOMe
/Cl
=I+<. \C/
GOOMe
+-
BuZnCl
/\
c5HiI
kCOOMe
(XIX)
n- Butyl(dimethy1 dition
38 . [:I
Refen?scesp_ 112
malonato)zinc
exclusively
undergoes
conjugate
ad-
J.G. NOL*:.
94
Three-membered ethylzinc NMR
chloride
ring
formation
with methyl
the product
of this
reaction
is
H
\ /
/
c=c
\
As
cis-dimethyl
(XXI).
upon interaction shown
of
.~
by IR and
1-propyl-2-chloro-
The following
reaction
scheme
.
consider.ed
H
occurs
c-chloroacrylate.
-1,2-cyclopropanedicarboxylate was
also
1391:
Cl f
EtZnCl
<
n-Pr--_C.
6 YFO
COOMe
0 ZnCl
&Me
(XX)
H
(XX)
-IH
\ /
c=c
/ \
Cl
:
ZnCl
COOMe OMe
COOMe
(-ZnC$)
>
n-Pr
-
COOMe
k4 =?z
Cl
(XXI)
The allylic
reaction
of allylzinc
rearrangment,
e.g.
reagents
with
cx-alkoxyketones
involves
40- : Cl
G2%CH=CHCH2ZnBr
C~=CK-CH(C2H5)-~C3~)(OH)-CErZOCIK
.-.
95
ZINC
o-Alkoxyesters yield. upon
afford
Pentenylzinc reaction
r
observed
reagent
with
alkoxycarbinols
diallyl-substituted
ethyl
affords
a
3/l
mixture
of (XXII)
the formation
ethoxyacetate;
in excellent and (XXIII)
of (XXIV)
is not
..
40 i .
-2
C~=CH-CH(CZHS), ,
CH(OH)C%OC&
(XXII)
C%=CH-CH(C&
CJ+=CH--CH(C&
\ ,
CZHSCH=CH-C~
CH(OH)C~OCzHg
(XXIII)
C&.CH=CH-C~, CH(OH)CI$OC2Hg
CZHSCH=CH-CH/
The
formation
reaction
of diallyl-substituted
of imino
the intermediate gested,
via
ethers formation
an isonitrile
PhNH=CHOEt
+
?
PhN=CHR
The
reaction
to otherwise amines
with
allylzinc
+
with
bromide base
Rg)
organozinc
available
RNHCRr3,
amines
e.g.
the
proceeds
as previously
via sug-
.-> -MOR
(I-$0)
PhNHCH3
compounds
symmetrically kg:
from
probably
and not,
P&N-CH-R
Y Ph-N-CH(
of isonitriles
of the type
Referencesp. 112
RM -
difficultly
secondary
of a Schiff _ . L4lj:
RM
(XXIV)
offers
substituted
a route secondary
J.G. NOLTES 1:.
96
Ph--N=C:
+
THF w
3 CH2=CHCH2ZnBr
PhNHC(C%CH=C%)3
;1
0-p (30%)
Such
compounds
reaction
may
of allylzinc
be obtained bromide
(OEt),
Ph-N=C
attractive
yields
via the
@2j:
with iminocarbonates
RM
f
in more
“: yEt
__,
Ph-&-C(R)OEt
/
6MOD)’
PIrN=C(R)OEt
+
RM
9
.
Ph-I++ (-MOEt)
PhN=CR,
Y
+
-
(RM
With
substituted
rearrangment
allylzinc stops
reagents
=
PhNHGR,
CH2=CHCH2ZnBr;
the reaction
at the iminoether
stage
which
yield
involves
61%)
allylic
@q:
,OEt PhN=C(OEt)2
Nivert
+
RCH=CHCH2ZnBr
and Miginiac
derived
from
affords
a mixture
former
strongly
have
propargylbrornide
shown
CH2=C=CHZnBr
PhN=C, (R=Me;
66%)
(R=Et;
40 ‘$11
that the organozinc
with gem-aminoethers
of the acetylenic predominate
___3 (%O)
and allenic
amines
CHRCH=C%
reagent
or with aldimines in which
the
[4g : KC= CC%CH(R)N(C,%)2
+
iV@
C4h$OCH(R)N(C
zH5)2
CI-$=C=CHCH(R)N(C,H$2
. ..I : :._.
ZINC
97
CH2=C=CHZnBr
HC= CCH2CH(C&NHR
-I-
-IF
CbHSCH=NR
An independent bases
was
tained
mixtures
obtained vation
of the reaction by Moreau
in yields
with
and secondary
of the ring occurs Whereas carbon
atom,
alifatic
carbon
H4
of
inversion
the
Ph.
et al.
opening
with
=.c-_y ‘0’
!I R, 2R)
Referencesp. 112
reagent
yield
amines
43j. c
have
:H \Me trans
as well
or with
exclusively
the highly
1-phenyl-1,2-epoxypropane
(1 S, 2 R) cis-isomer
atom
nearly
reacts
ob-
having
been
reagent
obser-
derived
aldimines
affords
reactions
of
cr-allenic
stereospecific
nature
by diallylzinc
at the benzylic reacts
also
the interesting
the corresponding
established
of configuration
the latter
made
with Schiff
authors
of the organozinc
amines,
(1 R, 2 R)trans-epoxide the
L. Miginiac
bromide
These
amines
gem-aminoethers
acetylenic
l-bromo-butyne-2
Abenhaim
44j.
the condensation
exclusively
tertiary
and allenic
up to 54%
whereas
of allenylzinc
and Gaudemar.
of acetylenic
3-bromobutyne-1
nearly the
study
reported
that
from
CH2=C=CHCH(C&)NHR
exclusively to a small
carbon
which
atom.
at the benzylic extent
at the
E5]:
Al12Zn
cyo) 3-phenylhexene-4-ol-
I(2 R, 2 S)
zmc
99 _j,
CF$=CHC~
\
MgBr
/
c=c
Ph /-
YznBr
(30) i C~=CHC~
\ Ph
/
(22%)
C=C%
C%=CHCH2ZnBr PhC=CMgBr (65%)
‘y-%3
e$_a T
C%CH=CH2 l/2
CIY-$CH=C%
.ZnBr
I 3
Ph-C-C~MgBr
\ I
With place
vinylic at 35O,
organometallic e.g.
C33CH=CHMgBr
reagents
an exothermal
.&lBr
addition
takes
@6]:
t
C%=CHCH2Zn&
c3H7, CH-CH CH2=CHCy/,
/
\
ZnBr
Mg Br
(~0) I CH2=CHC~~~(~~!)~3~7 (58%)
Referencesp. 3 I2
J_G_NOL~“‘-.;
100 C.
Carbenoid The
continued in organic The has
reactions
of organozinc
carbenoidreactivity
to attract attention and further and
organometallic
synthesis
sub.ject of carbenoid
reagents
of their
examples been
application
area
pi'].
have
dealt with synthetic
Simmons-Smith
reagent
Gem-dimethylcycloheptadienes
compounds
on the author's
applications
zinc-copper
have
of 5,5-dimethyl-Z-cyclohexanol
OWII
couple/methylene
beenpreparedvia
coupled
of the
coniodide.
cyclopropanation
with homoallylic
ring expansion
48': Ll
Zn-Cu
L480JoHBr 2.KOH/EtOH
GH21z
The
Simmons-Smith
selective
The
route
corresponding
stereoselective -bicycle
b.l.O]d
:. :
published.
of halomethylzinc
with emphasis
has
:
in this
Severalp'apers ventional
organozinc
have
reactions
beenbrieflyreviewedbyseyferth
contributions
-_ _. '.
compounds
of appropriate
-.
reaction
of cycloocten-
to anti-bi-cycle
reaction route
-1 6.l.O~nonan c
-2-01
of cis-cyclononen-3-01
(less than 0.05%
ecan-Z-01
3-01
(XXVI)
of E-epimer
i50]:
afforded (XXV)
a stereoc49]:
affords
ahighly
formed)
to anti-
101
ZINC
OH
OH
Le Perchec
and Conia
obtained bicyclopropylidene
of vinylidenecyclopropane
Templeton
Fg:
and Wie have investigated
(3o- and 3@-hydroxy, 5,6-unsaturated
the effect of IS-oxygen functions
3o- and 3S-acetoxy,
3-ethylene
acetal) of
steroids on the addition of the Simmons-Smith
to the steroidal 5,6-double bond. studied, only
via cyclopropanation
in the presence
take place with timation
Of the various
of the
3o-hydroxy
of the expected
5-cholestene
reagent derivatives
function did reaction
3cr-hydroq-5,6
a-cyclopropano-
-5o-cholestanc
Furukawa
et al. have continued
iodoalkane/diethylzinc authors
(AS 69;
Referencesp.112
225).
their investigation of the gem-di-
cyclopropanation
reagent discovered
by these
J.G.NOLTES t
102 The reagent
relative
reactivity from
generated
decrease
diethyloinc
in the order
hexene>hept-1-ene with alkyivinylethers
styrenes
(p-value
RZnCH$
(XXVII)
carbene
(ROCH=CI$)
The
effects,
the
R--in
methylene
iodide
outcome
1s - a more
same
group
/diethylzinc
tance
has
of steric in addition
of experiments suggests
nucleophilic
The
studied
with substituted
that methylene
in reactions much
of the
PhCH$-EsZn
I
carbenoid
transfer
reactionthanthat
the stereoselectivity
= 6.6 for the same
zinc carbenoid
lithium
to
by
of dichloro-
(XXVIII)
with cyclohexene
of coordination
0
Experiments
.,__,‘~~
by the phenylcarbenoidis
(syn/anti --
to
$4.
reagent
for the reaction
found
>trimethylethylene>cyclo-
(XXVII)
The
was
and&-alkenylethylethers
importance
of -1.61+0.05)
(XXVIII)
the zinc carbenoid
of decreasingnucleophilicity).
revealed
electronic
and
tetramethylethylene
(order
(RCH=CHOC&)
of olefins towards
shows 541. c
with olefins. higher
of the benzaliodide/
Thee-selectivity
in ethers
(e.g. c/anti
in diethylether)
reaction solvent
in pentane)
to the metal
shown = 17.1
than in hydrocarbons indicating atom
the impor-
c541:
>
larger=-selectivitythanthe
corresponding
103
ZINC
Interestingly
reagent
E5Zn/CI-$+2 where
the cyclopropanation
air was
is greatly
passed
shorter
yields with
as compared
atmosphere
formation
diethylzinc
experiments
-t
dominating
are
much
anitrogen
type
cyclohexene.
authors
of reaction
intermediate
These
or
route
to
d?splays and
(42%)
of EtZnCCb PhHgCC$)
and
is postulated
E-selective
as
behaviour
7-bromonorcarane
pre-
E6].
observed
reactions
vH
for the bromocyclo-
derivative
in their investigation
dichloropropylzinc
by elimination
References p. 112
of
of the fluorocyclopropane,
CHBr21
7-chloro-
of the interaction
the formation
as well
carbontetrachloride
rormation
(via PrHgCC$
and
their z-isomers
1-chloropropene with
synthetic
and/or
the preparation
zinc with polychloromethanes and
a novel
m
+
of 7-fluoro-,
over
Russian
pene
times
at a
of zinc by the interaction
A dihalogenomethylzinc
This
the endo-isomers
mediate
reaction
performedunder
offers
CHXYI
the mostusefulfor
derivative.
reaction
and
mixture
derivatives:
E5Zn
-I-
an intermediate.
(41%)
In experiments
the reaction
improved
for the chlorocyclopropane
propane
above
with trihalogenomethanes
I
was
CHCSI
by oxygen.
of halogenocarbenoids
halogenocyclopropane
CHF21
are
of olefins by the
[55j.
The
0
accelerated
into the space
rate of 10 ml/minthe
reaction
believed
carbenoid. into the
Zn-C
derivatives
isomerization
of ethyl chloride
as dichloronorcarane,
was.carried were
of dietbyl-
if the
out in the presence to proceed
Insertion bond which
of
via the inter-
of dichlorocarbene
of EsZn yield
affords
l-chloropror- 7 of ethylchlorocarbene i571: ._ -:
J.G. NOLTES
104
Seyferth
and Andrews
of halomethyl
derivatives
iodomethylzinc
iodide metal
appropriate
-t
These
works
best
iodomethyl nitrile.
may
derivative
involve
paper
a two-step
(AS 65;
n-Bu$iH
46)
n-B
Y
Furukawa and organotin
ethylidene
38
et al. hydrides
(cf.
3
metal
prepared
bromide
SiCHI
from
by the
and of the in aceto-
of the
bond in organosilanes
or reduction-alkylation
The
exclusive
the reaction
of IC%ZnI
formation
of a mixture
shows
of
of E
that the direct
s
SiD
insertion
58 . c1 have
investigated
with the
AS 65;
the reaction
E?Zn/RC% reacts
reagent.
with insertion
46) :
EtZZn/RCHs RzR3SiH
chloride
that interaction
ZnClI
The procedure
by the reaction
or silver
alkylation-reduction eliminated.
attack
+
bromomethyl
with the silicon-hydrogen
was
of
with the
Me,SnC%I
center.
corresponding
the possibility
of triorganosilanes group
in THF
nucleophilic
heavy
best
silver
with an excess
is operative
in a variety
are
with
reagent
E5SiCE_LLD and
process
The
synthesis
e.g.
Me$nCl
as involving
at the electrophilic
In the same
sequence
and
pictured
compounds
Simmons-Smith
halide,
of their
via the reaction
bromide
IICHZ ZnI L -
C?I-transfer.
chloromethyltin
the details
and mercury
1
THF -*
are
for
lead
of tin,
or organometallic
reagent
XC%ZnX
published
or bromomethylzinc
Zn-Cu
reactions
have
p
R1R2R3SiCyR (R=H
or Me)
of organosilicon The Si-H
bond
of a methylene
or
:
105
ZINC However,
iodide
in the reaction by the organotin
methylene
group
oftriethyltin
hydride
into the
reactivities
of substituted
noid yielded
a
and
insertion,
ethylene
-1.31
p-value
(AS 69;
both
reactions
predominates
Sn-H
over
Hammet
bond.
of -1.11 LO.03
and
methylene
suggesting
correlations towards
of the
of relative
the zinc
-1.19tO.05
insertion
a similar
of the organic
the insertion
as compared
respectively,
259)
reduction
aryldimethylsilanes
for the corresponding
mercury
hydride
carbe-
for methylene
witha
p-value
of
via bis(bromomethyl)-
transition
state (XXIX)
for
59J: C' Me
/\ cl-
I 6f Si
--------H
I’\
X-
:’
'\ 6-t' ;C+lR I \ / \ . \ z.:______:y
Z=XZn,
R=H,
Z=XZn,
R=Me,
Y=I Y=I
Me
Z=HgCI-$Br,
R=H,
Y=Br
~XXIX)
III. ORGANOZINC Several organozinc Abstracts
COMPOUNDS papers
providing
compounds of patent
AS
POLYMERIZATION
details
on the catalytic
in polymerization applications
and
reactions
patents
catalysts
pounds
of the catalytic
appeared
such
has
system
Referencesp.112
Abstracts,
presentedan
polymerizations
as brought
catalyst
components
in Chemical
Kuntz epoxide
of the
about
with
will not
excellent emphasis
by zinc-containing
di-isobutylaluminium
properties
have
describing
multi-component polymerization as one
CATALYSTS
containing
of
appeared. a variety
organozinc
system,
which
of comhave
be surveyedhere.
survey
of the mechanism
on coordinative
of
polymerizations
initiator systems
bo].
The
acetylacetonate/diethylzinc/water
J.G. NOLTES
106
was
found
zation The
to be particularly
of propylene
maximum
water
bonds
revealed
l$Al khich
groups
present
and that the vn
compound
as
shown
‘Zn
The
zinc
atom
and aluminium
may
type,
was
both
study
at a maximum
that the active
Al-O-Al
coordinated
for
and
has the cata-
R-Al
to the Al-O-Al
64:
/R
play
a major
FO,
is
A kinetic
speculated
requires
component
in (XXX)
R
It was
of
with all the metal-
components. rate
61 . CJ
when the amount
to react
polymerization
of the living
the copolymeri-
and allylgiycidylether
required
%O/F$Zn.
about
is observed
in the catalyst
acac /0.5 is
to polymer
than that
that the initial
system lyst,
is less
in bringing
epichlorohydrin
oxide,
conversion
present
-carbon
effective
a major role
role
in polymer
in epoxide chain
monomer
growth
coordination
[60]:
OCHCI$OCHC%OR
107
ZINC
-?2 =:
c
rH3
/ ,O,,
,0CHCF~OCHCX~OCHCH20R
2'zh /
Recent have
d
'. ..,??I
from
papers
clarified
several
dialkylzinc
catalyst
Et2Zn/H20
system
systems.
presence
of both
62. Cl
kinetics
The
The
Zn-0
and
of the
Zn-Et
diethylzinc/water
metric
polymerization
active
polymer
Tsuruta
active
pound:
the polymerization
the antipode
resulted
monomer
in restoration
of catalyst
-stereoselective.
If, however,
to the deactivated
catalyst,
tivitywas
regenerated
of styrene
oxide
/(-)-menthol Referencesp. 112
has
k5].
Fj. been
effected
asymmetric with
been
with
com-
poly-propylene
oxide
following
addition was
dialkylzinc asymmetric
selection
the catalyst
brought
(+)-bis(2-methyl-
but the catalyst
catalyst
by
acids
dialkylzinc
with
active
Asym-
realized
L-o-amino
of diethylzinc
the optically
The
earlier
active
the
of an optically
by the further
activity,
an active
E3]. 2
active
Addition
catalyst
discussed
69; 227) has
oxide
species
using
with
(AS
optically
63. C
of the asymmetric
deactivation
compounds
an optically
afforded
catalyst
(formation
of DL-propylene
catalyst
been
the
oxide
mixture)
as cocatalysts
et al. by using
butyl)zinc/water
leaving
dialkylzinc
alcohols
by Furukawa
monomer
is im-
activity requires
of propylene
(l/2) has
of the
oxide
in the active
of epoxides
a racemic
et al. by using
or optically about
from
catalyst
bonds
initiated by
reproducibility
of propylene
polymerization
initiator system selection
catalytic
Et2Zn;
University
polymerizations
for the polymerization of free
at Kyoto
of Furukawa
of epoxide
aspects
by the removal
proved
the group
etc.
of water nonwas
added
selec-
polymerization
system
diethylzinc/
J.G.NOLTES:.
.108
Sakata
CY, $-unsaturatedketone propylene
catalyst
-dimethylacrylophenone
Conjugate gives
of EsZn
addition
a catalyst
were
and
Tsuruta
fruitful studies
dealing
the area
of carbon EtzZn/%O unitinthe following both cases trans
at Tokyo
wit__ '-the application catalysis.
with
polycarbonate alkaline the
showing
system
bil.
hydrolysis
or
in the ring opening
is
configuration
r7 1_66J-
was
of the
specifically inverted
their in
is their
copolymerization
(EPCH)using
-reduction
1,2-cyclohexanediolformed that the
ineffective.
interest
alternate
(cis ortrans) --
LiAlH4
other
compounds
of
Th e configuration
. _
@,B-
(AS 69; 224)
of organozinc
Of particular of the
copolymer
and
were
continued
have
cis-1,2-epoxycyclohexane
(l/l) catalyst
of
stability at high temperature
University
of the stereochemistry
dioxide
acrylophenone
or methylacrylate)
activity and
of polymerization
investigation
for the polymerization
to cu,@-u&aturatedketones
with better
of diethylzinc/
but carbonylcompounds
suitable,
2-furylacroleine
(e.g.
Inoue
systems
$!I<3. Methilisopropenylketone; .. -
oxide
than ketones
the effectiveness
demonstrated
et al. have
was
a the
EPCH
determined
of the copolymer.
In
found to be exclusively
EPCH
carbon
atom
involved
during
the copolymerization
k7: LI
Et2Zn/J+0 f
Hydrolysis
nCO2
of poly-(propylene
polymerization
carbonate)
of R-(+)-propylene
oxide
obtained
by alternating
with carbon
dioxide
co-
using
a
I E%Zn&O
catalyst,
tollowed
resultedintransformation propylene
by treatment
of the epoxide
glycolbis-p-nitrobenzoate.
with p-nitrobenzyl unit of the copolymer
Determination
chloride, into
of the optical
109
ZINC
activity
of this
asymmetric fore,
ester
revealed
carbon
atom
of the epoxide
the organozinc-catalyzed
at the
methylene-oxygen Kawakemi
ring
linkage
and Tsuruta
or methyl
Methyl
in toluene,
type
catalyst
with
methyl
zation
or .THF,
68 . II
activity
n-
for
acrylate
carried
using
n-Bu;!Zn
results
studies
pj. with
or
n-butyl-
of the copolymeri-
indicate
but in HMPT
out
(HMPT)
or copolymerized
The
as kinetic
of diethylzinc system
place
as a third
allowed
methacrylate.
takes
obtained
a radical-type
an anionic
mechanism
cocatalyst
the block Under
and products
copolymerization
certain with
in a Ziegler-Natta
conditions
controlled
of ethylene no homopolymeri-
composition
could
be
[69].
The
valence
polymerize
state
propylene
relationship
or the molecular
A.
as well
mechanism
was
triamide
solution
as a catallyst.
predominantly
of methyl
the polymerization
or HMPT
in toluene
The use
served
catalytic
There-
38 . Cl
applies
direct
place
an anionic
can be polymerized THF
experiments
polymerization
takes
a low
of the
copolymerization.
or hexamethylphosphoric
(dimethylmalonato)zinc zation
indicating
provided
o-chloroacrylate
styrene
opening
configuration
in the polymerization
methacrylate
in dimethylsulfoxide
of the
upon
observed
-butyl(dimethylmalonato)zinc
IV.
the inversion
of titanium
in the
to isotactic
between weight
the
EsZn/TiC13
polymer Ti
2f
or isatacticities
has
content
been
and the
catalyst
used
investigated. catalyst
of the polymers
was
A
activity not ob-
70 . Cl
STRUCTURAL,
Structural An X-ray
Referencesp. 112
SPECTROSCOPIC
AND
PHYSICAL
STUDIES
studies crystal
structure
determination
of the anionic
zinc..-
to
J.G. NOLTES
110 -borane
complex
-decarborato)zincate The
structure
ligands
kSMeP]2
can be considered
Fig. 1. Structure boron
(Af, 1971,
The
only cfrom
been
reported
two bidentate
to zinc (Fig-
EloHlzZ-
1).
s h owing
N.N.Greenwood
[7q.
the positions
etal.,
of the
J.Chem.Soc.
Skj.
studies
IR and
Raman
spectra
methylzincate
7L$Zn(C3)4,
reported.
spectra
2n-C
has
to comprise
of i;'~MeI$~n(B10H12)2]
atoms
B. Spectroscopic
band
kn(BloH12)d
co-ordinatedtetrahedrally
zinc and
bis(dodecahydro-nido-.
methyltriphenylphosphonium
The
at 520 cm
-1
stretching
of the isotopic
6 L5Zn(CH-$+
indicate
Td
in the IR spectrum mode
bill.
symmetry
analogs
and
of lithiumtetra-
7L$Zn(Cnj)4
around
of 'Li2Zn(CD,),
the zinc
been
have atom.
isassigned
A
to the
111
ZINC A iodide
PMR in THF
solution
alkyl exchange PMRtime
(corresponding
to the
Oliver
et al. have
of
ZnI2
in going
of
borate(2-1 Travers
the
anionic
ion
groups
and
for changes
kinetic
solvent
equi-
AS
28.87
*
MHz
on the rate and dimethylzincparameters
are of the
(dichloromethane,
solvent
eu) to a strongly
(diethylether,
coordinating
solvent
= + 2 eu). and
80.53
MHz
llB-NMR
of the dodecahydro-nido-deca-
complex
were
of zinc iodide)
in the mechanism
coordinating
has
~e4Nj2[Zn(BloH12)21
[7] and the results
on the
1.00/1.05
the Schlenk
in the system
energies
of the
zinc
amount
effects of solvent
a non-coordinating
discussion
is slow
(R=Me,Et)
the
AS #= z-14
173j. At -70°
ratio was
that
ethylzinc
500 at -9OO):
Ea f' = 16.3 kcal/mole;
A detailed spectra
studied
to a "weakly"
(triethylamine,
Zn/i
with a small
2RZnI
is presented
9 ..1 kcal/mole.
the
and
et al.
diaikylzinc
confirming
Activation
from
and
in which
of methyl
.- ? p41.
< 5 kcal/mole)
Ea '=
0
for methyl-
by Evans
iodide
right (K>
exchange
Evidence
reaction
reported
observedat-90°
+
trimethylindium
Ea
solutions
52Zn
reported.
been
to "alkylzinc.iodide"
line was
mechanism
equilibrium
alkylzinc
For
lies well
librium
has
between
scale.
only one
of the Schlenk
study
been
correlated
presented with
by Greenwood
the known
and
structure
L711 in the solid state. t-Butoxy in
radicals
the presence
tion at the cavity t-BuO=
metal
of diethylzinc centre.
the E.S.R. +
Et2Zn
Referencesp.112
generated
induce
of di-t-butyl.peroxide
an homolytic
If the reaction
spectrum -+
by photolysis
is carried
bimolecular.
out in an E.S.R.
of the ethyl radicaicanbe EtZnO-t-Bu
-I- Et.
substitu-
observed
75 : [I
J.G.EiOLTEs..’ :
112
C.
Other
physical
Complex with
studies
formation
2,2’-bipyridine,
ethylene
ethylene
diamine
stoechiometry
(CH_&Zn,
of
has
been
diamine
studied
and dissociation
agreement
with earlier
(C21-I$2Zn and
(iso-C3I-&-Zn
N,N,N*,N’-tetramethyl-
by an oscillometric
constant
results
and
method.
of the complexes
(AS 67; 235)
The
were
in
fi61. -3
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