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The hydridopentafluorophosphate anion [PF5H]−
INORG.
NUCL..
CHEM.
LETTERS
Val.
5,
pp.
295-299,
1969.
Pergamon
THE HYDRIDOPENTAFLUOROPHOSPHATE
Press.
ANION
Printed
In
Great
Britain
[PF~N]-
J. F. Nixon and J. R. Swain The Chemical Laboratory, Brighton,
University
BNI 9QJ, Sussex,
of Sussex,
England.
(Recelv~ 23 Dec~be, 1~8)
We wish to describe phosphate
ion
syntheses
of the novel hydridopentafluoro
[PFsH ]- (I) which has been identified by its
characteristic
proton and fluorine nuclear magnetic
resonance
spectra. H
(I)
F(1) F(2) Trifluorophosphine room temperature
and potassium in the presence
bifluoride
react on shaking at
of acetonitrile
according
to
equation i. PF 3 + HF 2
room temperature .> [PFsH ] in CH 3 C~!
The most likely mechanism would seem to involve dissociation
of HF 2
to hydrogen
(a) initial
fluoride and fluoride ion,
(b) addition of HF to PF 3 to give the pentaeoordinate followed by (c) nucleophilic acid PF~H.
Step
(i
attack by fluoride
ion on the Lewis
(a) is known to occur in aqueous
295
PFL}{
solution
(i),
296
HYDRIDOPENTAFLUOROPHOSPHATE ANION IPFsHI"
and r e c e n t l y
it has been shown that a l k y l or aryl f l u o r o p h o s p h i n e s ,
R n P E 3 _ n, do r e a d i l y add h y d r o g e n phosphoranes
Vol. 5, No.4
RnPF~-nH
reported
addition
phoranes
(4)-
(n = 1,2)
of fluoride
We have also obtained aminodifluorophosphine
fluoride (2,3).
producing
the fluoro-
Ivin and coworkers
have
ion to alkyl and aryl t r i f l u o r o p h o s -
(I) from the r e a c t i o n between d i m e t h y l -
and p o t a s s i u m b i f l u o r i d e
possibly according
to e q u a t i o n 2. 70 o M e 2 N P F 2 + 3HF 2 -
~ [Me2NH2] + + [PFsHj
+ 3F
(2)
in M e C N Hydrogen
fluoride
p r o d u c e d via
phosphorus-nitrogen which
(a) would
immediately
bond of He2NPF 2 g e n e r a t i n g
cleave
trifluorophosphine
then reacts with excess HF 2- as in e q u a t i o n i.
amounts
of b i s ( d i m e t h y l a m i n o ) f l u o r o p h o s p h i n e ,
formed in a side r e a c t i o n
the
Very small
(He2N)2PF , are also
involving aminolysis
of d i m e t h y l a m i n o
difluorophosphine. Further
support
comes from the r e a c t i o n b e t w e e n d i m e t h y l a m i n e
and t r i f l u o r o p h o s p h i n e , suggested bifluoride
originally
that the solid residues
the b i f l u o r i d e
~
the d i m e t h y l a m m o m i u m
2Me2NPF 2 + (He2~2)+[KF2] -
salt might
difluorophosphine
formed,
excess,
to equations
according
solution
excess PF 3 .
then react w i t h
the d i m e t h y l a m i n o
or w i t h any t r i f l u o r o p h o s p h i n e 2 or i, again p r o d u c i n g
ion, and this has been confirmed nitrile
contained
(5), who
salt. 3 M e 2 N H + 2PF 3
However
studied by Cavell
by n.m.r,
of the solid products
studies
present
the
in
[PF~H!-
on an aeeto-
from the r e a c t i o n u s i n g
Vol. 5, No. 4
HYDRIDOPENTAFLUOROPHOSPHATE ANION IPFsH!"
297
The proton n.m.r, of (I) consists of a widely spaced doublet of quintets from spin coupling with phosphorus and the four F(I ) fkuorine nuclei.
There was no resolvable splitting of these lines
by further interaction with the fluorine nucleus F(2 ) trans- to hydrogen.
The fluorine n.m.r,
spectrum which may be interpreted
on a first order basis consists of two doublets of doublets for the resonance of the F(I ) nuclei, because of spin coupling with phosphorus, hydrogen and the unique fluorine F(2), together with the expected weaker doublet of quintets for the F(2 ) resonance. Chemical shift and coupling constant data for [PFsH ]- (I) are summarised in Table I. Table I Chemical Shift and Coupling Constant Data for K + [PFsH ]- in MeCN TH
4.6 a
JF(1)F(2 )
41
c./sec.
mF (1
+36.4 b
aF(2)M
"-o c./seoo
mF (2
+66o2 b
JF(1) H
126~ c./sec. 128~ c./sec.
aeF(l aeF(2
817 c./sec.
JPH
955
c./sec.
729 c./sec.
In p.p.m.
[rel.external SiMe~ : i0] t
From 19F spectrum
b ~
In p.p.m, tel. CCI3F. From IH spectrum
I~ is interesting to note that the coupling constant 2J(HPF ) between hydrogen and the trans-fluorine, F(2 ), ls very small (possibly zero), and inspection of the rather limlted available data for pentavalent phosphorus compounds (summarised in Table II), suggests that the magnitude of 2J(HPF ) depends not only on the nature of
298
HYDRIDOPENTAFLUOROPHOSPHATE ANION [PF$H]"
the other groups attached angle,
and increases
to phosphorus
but also on the HPF bond
as the HPF angle decreases. Table
Variation
Voh 5, No. 4
of 2J(HPF )
II
(c./sec.) with the HPF bond angle
in pentavalent
phosphorus
derivatives
(Approx. HPF bond angle) Compound
120 o
180 °
[HPFs]-
0
[CF3PF~H][ (CF3)2PF3H]-
18.0
90 o
Reference
127
this work
120
6
69.5
MePF3H
29.9
117
EtPF3H
3O
121
PhPF3H
31.5
124
Me2PF2H
3,8
98.4
Me-C6H~PF~H
34
118
References i.
D.G. TUCK, Progress p. 161, Interscience
2.
G.I. DROZD,
In Inorganic Chemistry,
S, Z. IVIN, V.V. SHELUCHENK0,
F. SEEL, W. GOMBLER,
9, 1968,
Publishers.
and A. D. VARSHAVSKII, .
Vol.
J. Gen. Chem.,
K. H. RUDOLPH,
B. I. TETEL'BAUM,
(USSR_~, 1968,
Z. Naturforsch,
38, 551. 23(b),
587, 1968. .
G. I. DROZD,
S. Z. IVIN, V. V. SHELUCHENK0,
G. 4. LUGANSKII 1967,
37, 1269.
and A.D. VARSHAVSKII,
B. I. TETEL'BAUM,
J. Gen. Chem.
(USSR),
Vol. 5, No. 4
HYDRIDOPENTAFLUOROPHOSPHATE ANION [PFsHI-
299
5o
R. G. CAVELL, J. Chem. Soc., 1964, 1992.
6.
R. G. CAVELL and J. F. NIKON, proc. Chem. Soc., 1964, 229.
7o
J. F. NIXON and J. R. SWAIN, Chemo Comm., 1968, 997.
8.
R. A. GOODRICH and P. M. TREICNEL, Inorg. Chem., 1968, ~, 694
9.
E. L. MUETTERTIES, W. ~ H L E R ,
Inorg. Chem., 1964, ~, 1298.
K. J. PACKER and R. SCNMUTZLER,
NUCL..
CHEM.
LETTERS
Val.
5,
pp.
295-299,
1969.
Pergamon
THE HYDRIDOPENTAFLUOROPHOSPHATE
Press.
ANION
Printed
In
Great
Britain
[PF~N]-
J. F. Nixon and J. R. Swain The Chemical Laboratory, Brighton,
University
BNI 9QJ, Sussex,
of Sussex,
England.
(Recelv~ 23 Dec~be, 1~8)
We wish to describe phosphate
ion
syntheses
of the novel hydridopentafluoro
[PFsH ]- (I) which has been identified by its
characteristic
proton and fluorine nuclear magnetic
resonance
spectra. H
(I)
F(1) F(2) Trifluorophosphine room temperature
and potassium in the presence
bifluoride
react on shaking at
of acetonitrile
according
to
equation i. PF 3 + HF 2
room temperature .> [PFsH ] in CH 3 C~!
The most likely mechanism would seem to involve dissociation
of HF 2
to hydrogen
(a) initial
fluoride and fluoride ion,
(b) addition of HF to PF 3 to give the pentaeoordinate followed by (c) nucleophilic acid PF~H.
Step
(i
attack by fluoride
ion on the Lewis
(a) is known to occur in aqueous
295
PFL}{
solution
(i),
296
HYDRIDOPENTAFLUOROPHOSPHATE ANION IPFsHI"
and r e c e n t l y
it has been shown that a l k y l or aryl f l u o r o p h o s p h i n e s ,
R n P E 3 _ n, do r e a d i l y add h y d r o g e n phosphoranes
Vol. 5, No.4
RnPF~-nH
reported
addition
phoranes
(4)-
(n = 1,2)
of fluoride
We have also obtained aminodifluorophosphine
fluoride (2,3).
producing
the fluoro-
Ivin and coworkers
have
ion to alkyl and aryl t r i f l u o r o p h o s -
(I) from the r e a c t i o n between d i m e t h y l -
and p o t a s s i u m b i f l u o r i d e
possibly according
to e q u a t i o n 2. 70 o M e 2 N P F 2 + 3HF 2 -
~ [Me2NH2] + + [PFsHj
+ 3F
(2)
in M e C N Hydrogen
fluoride
p r o d u c e d via
phosphorus-nitrogen which
(a) would
immediately
bond of He2NPF 2 g e n e r a t i n g
cleave
trifluorophosphine
then reacts with excess HF 2- as in e q u a t i o n i.
amounts
of b i s ( d i m e t h y l a m i n o ) f l u o r o p h o s p h i n e ,
formed in a side r e a c t i o n
the
Very small
(He2N)2PF , are also
involving aminolysis
of d i m e t h y l a m i n o
difluorophosphine. Further
support
comes from the r e a c t i o n b e t w e e n d i m e t h y l a m i n e
and t r i f l u o r o p h o s p h i n e , suggested bifluoride
originally
that the solid residues
the b i f l u o r i d e
~
the d i m e t h y l a m m o m i u m
2Me2NPF 2 + (He2~2)+[KF2] -
salt might
difluorophosphine
formed,
excess,
to equations
according
solution
excess PF 3 .
then react w i t h
the d i m e t h y l a m i n o
or w i t h any t r i f l u o r o p h o s p h i n e 2 or i, again p r o d u c i n g
ion, and this has been confirmed nitrile
contained
(5), who
salt. 3 M e 2 N H + 2PF 3
However
studied by Cavell
by n.m.r,
of the solid products
studies
present
the
in
[PF~H!-
on an aeeto-
from the r e a c t i o n u s i n g
Vol. 5, No. 4
HYDRIDOPENTAFLUOROPHOSPHATE ANION IPFsH!"
297
The proton n.m.r, of (I) consists of a widely spaced doublet of quintets from spin coupling with phosphorus and the four F(I ) fkuorine nuclei.
There was no resolvable splitting of these lines
by further interaction with the fluorine nucleus F(2 ) trans- to hydrogen.
The fluorine n.m.r,
spectrum which may be interpreted
on a first order basis consists of two doublets of doublets for the resonance of the F(I ) nuclei, because of spin coupling with phosphorus, hydrogen and the unique fluorine F(2), together with the expected weaker doublet of quintets for the F(2 ) resonance. Chemical shift and coupling constant data for [PFsH ]- (I) are summarised in Table I. Table I Chemical Shift and Coupling Constant Data for K + [PFsH ]- in MeCN TH
4.6 a
JF(1)F(2 )
41
c./sec.
mF (1
+36.4 b
aF(2)M
"-o c./seoo
mF (2
+66o2 b
JF(1) H
126~ c./sec. 128~ c./sec.
aeF(l aeF(2
817 c./sec.
JPH
955
c./sec.
729 c./sec.
In p.p.m.
[rel.external SiMe~ : i0] t
From 19F spectrum
b ~
In p.p.m, tel. CCI3F. From IH spectrum
I~ is interesting to note that the coupling constant 2J(HPF ) between hydrogen and the trans-fluorine, F(2 ), ls very small (possibly zero), and inspection of the rather limlted available data for pentavalent phosphorus compounds (summarised in Table II), suggests that the magnitude of 2J(HPF ) depends not only on the nature of
298
HYDRIDOPENTAFLUOROPHOSPHATE ANION [PF$H]"
the other groups attached angle,
and increases
to phosphorus
but also on the HPF bond
as the HPF angle decreases. Table
Variation
Voh 5, No. 4
of 2J(HPF )
II
(c./sec.) with the HPF bond angle
in pentavalent
phosphorus
derivatives
(Approx. HPF bond angle) Compound
120 o
180 °
[HPFs]-
0
[CF3PF~H][ (CF3)2PF3H]-
18.0
90 o
Reference
127
this work
120
6
69.5
MePF3H
29.9
117
EtPF3H
3O
121
PhPF3H
31.5
124
Me2PF2H
3,8
98.4
Me-C6H~PF~H
34
118
References i.
D.G. TUCK, Progress p. 161, Interscience
2.
G.I. DROZD,
In Inorganic Chemistry,
S, Z. IVIN, V.V. SHELUCHENK0,
F. SEEL, W. GOMBLER,
9, 1968,
Publishers.
and A. D. VARSHAVSKII, .
Vol.
J. Gen. Chem.,
K. H. RUDOLPH,
B. I. TETEL'BAUM,
(USSR_~, 1968,
Z. Naturforsch,
38, 551. 23(b),
587, 1968. .
G. I. DROZD,
S. Z. IVIN, V. V. SHELUCHENK0,
G. 4. LUGANSKII 1967,
37, 1269.
and A.D. VARSHAVSKII,
B. I. TETEL'BAUM,
J. Gen. Chem.
(USSR),
Vol. 5, No. 4
HYDRIDOPENTAFLUOROPHOSPHATE ANION [PFsHI-
299
5o
R. G. CAVELL, J. Chem. Soc., 1964, 1992.
6.
R. G. CAVELL and J. F. NIKON, proc. Chem. Soc., 1964, 229.
7o
J. F. NIXON and J. R. SWAIN, Chemo Comm., 1968, 997.
8.
R. A. GOODRICH and P. M. TREICNEL, Inorg. Chem., 1968, ~, 694
9.
E. L. MUETTERTIES, W. ~ H L E R ,
Inorg. Chem., 1964, ~, 1298.
K. J. PACKER and R. SCNMUTZLER,