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Novel lithium cation complexants
Tetrahedron Letters No. 21, pp 1861 - 1862, 1978. 0 Persamon Press Lti. Printed in Ureat Britain.
s02,00/0
004~4039/78/0515-1861.
NOVELLITHIUMCATIONCCMPLEXANTS by Jean Grandjean and Pierre (a) Universit6 (b) Universit6
Laszlo::(a),
J.P.
de Liege - Sart-Tilman
des Sciences
et Techniques
Picavet
and Henri Sliwa::(b)
par 4000 Liege 1 - Belgium 59650 Villeneuve
de Lille,
(Received in UK 21 March 1978; accepted for publication
Two of us have recently cycloundecane
prepared’
new derivatives
d’Ascq
- France.
28 March 1978)
of l,lO-dioxa-4,7-diaza-ll-phospha-
Q) .
We report
here the complexing
Complexation
induces downfield
spectrometer
(Fig.)
aptitude
shifts
of these crowns 1,2 towards alkali
of the proton resonances
metal cations.
measured with a Varian T-60
(Table).
A&r) 10'
H3hNoNP-OR C
0'
H3CHNu
1
Using the observed solution
indicate
(K = 8-10 M-l) weak. Several
obtained
constants from the best
strong binding
we have extracted’ K and the limiting fits
of the lithium
from the data in acetonitrile chemical
of the theoretical cation
shift
6B in the bound
curves to the experimental
(K > 300 M-l),
while the sodium
and potassium lithium
(K = 5 M-l) complexes of these 11-crown-5 analogs (1, are rather 3-6 , cyclic decapeptides7 and cryptands 8 complexes with crown ethers
have been characterized. reported
stoichiometry,
at 35’C the stability
form. The K values points
1:l
R : CH3, C&
with 12-crown-44,
But such a selectivity 14-crown-43y5,
towards lithium
and the (2.1.1)
1861
as we find here has only been
cryptand8.
With a diameter of -ca.
Nq. 21
1862
R
salt
resonance
LiC104
C2%
NCH3
NaC104
CzHs
NCH3
NaSCN
‘ZH5
NCH3
NaSCN
CH3
NCH3
NaSCN
(II3
CCH3
KSCN
‘ZH5
NCH3
a) + 0.4 Hz, downfield
1.2 i,
the lithium
ion can fit
hole dimensions
are within
The lithium-complexing
this
in conjunction
of the lithium
with 12-crown-4
143.6
10.1
> 300
137.7
4.2
10
139.9
6.4
8
139.9
6.2
9
208.7
9.9
8
136.3
2.8
5
‘)at
35’C,+
15%
of 1.2-l .6 i 3. Strong interactions
12-crown-4,
14-crown-4,
and the (2.1.1)
with Li+
cryptand,
whose
range.
avidity
A number of important alkylation upon the structure
K(M-l)c
: summaryof the results.
into a cavity
with 11-crown-S,
A@z)b
b) + 0.6 Hz
from TMS Table
are indeed observed
IBM
10
of
(1, should be extremely useful
reactions
have rates
ion pairs , to drive
present’.
and/or
products
Derivatives
such reactions
for
synthetic
purposes.
very much dependent
of this
towards formation
type could be used, of specific
products . ACKNOWL~S
.
This work is part of the program “Binding of ions by organic subsidized
by Fonds de la Recherche Fondamentale Collective,
and bio-molecules”
Belgium.
REFERENCES.
(1) H. Sliwa and J.P. Picavet, Tetrahedron Letters, 1583 (1977). (2) D. Live and S.I. Chan, J. Am. Chem. Sot., 98; 3769 (1976). (3) J.J.
Christensen,
D.J. Eatough, and R.M. Izatt,
Chem. Rev.,
74, 351 (1974).
(4) F.A.L. Anet, J. Krane, J. Dale, K. Daasvatn and P.O. Kristiansen, 27, 3395 (1973). (5) C. J. Pedersen,
Fed. Proc.
(Fed. Am. Sot.
Exp. Biol.)
Acta Chem. Stand.,
, 27_, 1305 (1968).
(6) J. Dale and J. Krane, J. Chem. Sot., Chem. Connn., 1012 (1972). (7) I.L. Karle, J. Am. Chem. Sot., !4& 4000 (1974). (8) J.M. Lehn and J.P. Sauvage, Chem. Coma., 440 (1971); J. Am. Chem. Sot., 97_, 6700 (1975). (9) For instance : J.C. Dalton and B.G. Stokes, Tetrahedron Letters, 3179 (1975); T.M. Chan and B.S. Ong, ?etrahedron (10) C. Ouannes, G. Dressaire
Letters,
and Y. Langlois,
319 (1976).
Tetrahedron
Letters,
815 (1977).
s02,00/0
004~4039/78/0515-1861.
NOVELLITHIUMCATIONCCMPLEXANTS by Jean Grandjean and Pierre (a) Universit6 (b) Universit6
Laszlo::(a),
J.P.
de Liege - Sart-Tilman
des Sciences
et Techniques
Picavet
and Henri Sliwa::(b)
par 4000 Liege 1 - Belgium 59650 Villeneuve
de Lille,
(Received in UK 21 March 1978; accepted for publication
Two of us have recently cycloundecane
prepared’
new derivatives
d’Ascq
- France.
28 March 1978)
of l,lO-dioxa-4,7-diaza-ll-phospha-
Q) .
We report
here the complexing
Complexation
induces downfield
spectrometer
(Fig.)
aptitude
shifts
of these crowns 1,2 towards alkali
of the proton resonances
metal cations.
measured with a Varian T-60
(Table).
A&r) 10'
H3hNoNP-OR C
0'
H3CHNu
1
Using the observed solution
indicate
(K = 8-10 M-l) weak. Several
obtained
constants from the best
strong binding
we have extracted’ K and the limiting fits
of the lithium
from the data in acetonitrile chemical
of the theoretical cation
shift
6B in the bound
curves to the experimental
(K > 300 M-l),
while the sodium
and potassium lithium
(K = 5 M-l) complexes of these 11-crown-5 analogs (1, are rather 3-6 , cyclic decapeptides7 and cryptands 8 complexes with crown ethers
have been characterized. reported
stoichiometry,
at 35’C the stability
form. The K values points
1:l
R : CH3, C&
with 12-crown-44,
But such a selectivity 14-crown-43y5,
towards lithium
and the (2.1.1)
1861
as we find here has only been
cryptand8.
With a diameter of -ca.
Nq. 21
1862
R
salt
resonance
LiC104
C2%
NCH3
NaC104
CzHs
NCH3
NaSCN
‘ZH5
NCH3
NaSCN
CH3
NCH3
NaSCN
(II3
CCH3
KSCN
‘ZH5
NCH3
a) + 0.4 Hz, downfield
1.2 i,
the lithium
ion can fit
hole dimensions
are within
The lithium-complexing
this
in conjunction
of the lithium
with 12-crown-4
143.6
10.1
> 300
137.7
4.2
10
139.9
6.4
8
139.9
6.2
9
208.7
9.9
8
136.3
2.8
5
‘)at
35’C,+
15%
of 1.2-l .6 i 3. Strong interactions
12-crown-4,
14-crown-4,
and the (2.1.1)
with Li+
cryptand,
whose
range.
avidity
A number of important alkylation upon the structure
K(M-l)c
: summaryof the results.
into a cavity
with 11-crown-S,
A@z)b
b) + 0.6 Hz
from TMS Table
are indeed observed
IBM
10
of
(1, should be extremely useful
reactions
have rates
ion pairs , to drive
present’.
and/or
products
Derivatives
such reactions
for
synthetic
purposes.
very much dependent
of this
towards formation
type could be used, of specific
products . ACKNOWL~S
.
This work is part of the program “Binding of ions by organic subsidized
by Fonds de la Recherche Fondamentale Collective,
and bio-molecules”
Belgium.
REFERENCES.
(1) H. Sliwa and J.P. Picavet, Tetrahedron Letters, 1583 (1977). (2) D. Live and S.I. Chan, J. Am. Chem. Sot., 98; 3769 (1976). (3) J.J.
Christensen,
D.J. Eatough, and R.M. Izatt,
Chem. Rev.,
74, 351 (1974).
(4) F.A.L. Anet, J. Krane, J. Dale, K. Daasvatn and P.O. Kristiansen, 27, 3395 (1973). (5) C. J. Pedersen,
Fed. Proc.
(Fed. Am. Sot.
Exp. Biol.)
Acta Chem. Stand.,
, 27_, 1305 (1968).
(6) J. Dale and J. Krane, J. Chem. Sot., Chem. Connn., 1012 (1972). (7) I.L. Karle, J. Am. Chem. Sot., !4& 4000 (1974). (8) J.M. Lehn and J.P. Sauvage, Chem. Coma., 440 (1971); J. Am. Chem. Sot., 97_, 6700 (1975). (9) For instance : J.C. Dalton and B.G. Stokes, Tetrahedron Letters, 3179 (1975); T.M. Chan and B.S. Ong, ?etrahedron (10) C. Ouannes, G. Dressaire
Letters,
and Y. Langlois,
319 (1976).
Tetrahedron
Letters,
815 (1977).