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Comparative ESR studies of the polycrystalline alkali metal tetrafluorotetracyanoquinodimethan(TCNQF4) charge transfer salts
Physica 143B (1986) 518-520 North-Holland, Amsterdam
5]8
COMPARATIVE ESR ST[DIES OF THE POLYCRYSTALLINE ~(TCNQF 4) CHAR(~ TRANSFER SALTS
AI/KALI METAL
TETRAFLUORC/I~.'rKACYAND(~INODI-
M. Thomas Jones, Toshio Maruo, Susan Jansen*, James Roble, and Raymond D. Rataiczak'* Department of Chemistry,
University of Missouri-St.
Louis,
St. Louis, Mo. 63121, USA;
The entire series of alkali metal charge transfer salts of tetrafluorotetracyanoquinodimethan(TC~(~,) have been synthesized and studied by electron spin resonance(ESR) techniques. The tenperature 4dependence of the g-tensor, the temperature dependence of the relative magnetic susceptibility and the temperature dependence of the spectral envelope of each salt is discussed. The spectral properties of these salts are discussed in terms of the relationship between the size, electropesitivity, and other physical properties of the alkali metal ion as one moves through the alkali metal series. The lithium salt exhibits a temperature independent g-tensor and the magnetic susceptibility follows Curie Law from 77 to 300 K. The ESR envelope of the sodium salt consists of two overlapping spectra. The magnetic susceptibility of both species is thermally activated. The spectral envelopes of the potassium and rubidium salts are similar in shape and behavior. Both are strongly dependent upon temperature. Their magnetic susceptibilities are thermally activated. The potassium salt has been studied from ca 4 to 300 K. An abrupt change in the spectral lineshapes of the potassium and rubidium salts is observed at ca 150 K. Finally, the spectral envelope of the cesium salt displays a unique monotonic decrease in linewidth with temperature. able to grow single crystals of this salt in our
1. I ~ D t L - T I O N
Our
laboratory
magnetic salts
has
been
investigating
properties of various charge
and complexes of TCNQ and ~ 4
Studies
of
solutions of KTCNQ and
laboratories.
suspect
growing initiated
is
due
to
of
distributed electronegativity of TCN(~ 4 . We have
in
crystal
difficulty
transfer
KTCNQF 4
single
the
by
ESR.
a
We
the studies of the series of
metal
form ion pairs.
cation size and its electropositivity may effect
pairs
However, the structures for the
are
different
due
to
the
difference in the electronegativity of relative
to
hydrogen I .
polycrystalline show
samples
t_hat they
crystal
do
not
structures 2 .
Studies
of KTCNQ possess The
large
fluorine
solid
and
of
since the changes in
the micro-crystalline structure and of
single
obtained
crystals.
However,
The
isomorphous F~R
ESR
studies
of
the
to
whereas
~ 4
display
growth
have
not salts
asymmetric
demonstrate the effect of the differences in
line shapes and show considerable variation with
interaction
temperature.
structures of these salts.
In particular, an abrupt change in
polycrystalline
alkali-metal TCNQF 4 I: I salts 3 are reported here cation size, electropositivity,
of
the
single crystals of any of these
spectra of KTCNQ exhibit symmetrical line shapes those
we
the
yet.
~ 4
state
salts,
alkali-
ether type solvents indicate both anion radicals ion
TCNQF 4
the
energy
upon
the
and spin orbit microcrystalline
linewidth is observed at 150 K. A has
single crystal X-ray structure of not been reported,
yet.
KTCNQF 4
Nor have we
been
2. EXPERIMI~AL
TCNQF 4 was synthesized at the University
*Present address: Department of Chemistry, Cornell University, Ithaca, New York 14853, USA. **Department of Chemistry, Muskingtln College, New Concord, ohio 43762, USA. 0378 - 4 3 6 3 / 8 6 / $ 0 3 . 5 0 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division) and Y a m a d a Science F o u n d a t i o n
of
M.T. Jones et al. / ESR studies o f the polycrystalline alkali metal Missouri-St.
Louis and Musking~n College 4.
alkali-metal
simple salts were
the
for
methods
preparation
simple salts of TCNQ 5 . ~ 4 '
Its
synthesized of
Thus,
by
This
for Li,
The
room
salts
have
the
> 2M~-~qQP4 - + M+ + 13-
Rb
and
Cs 1:1 salts
were
prepared
from
the
ESR
of polycrystalline been
alkali-metal
order
spectra
studied
Several
and
the
TCNQF 4
there
are
NaTCN(~ 4 and
different
samples
salts were independently
to
of
alkali-metal
differences between
others.
NaTCN~" 4 The
temperature
series
considerable
3M+I - + 2TCSEF 4 . . . . . .
that all
3.2. ESR measurements
Na, and
CH3CN
shows
TCSEF 4 prepared are 1:1 simple salts.
alkali-metal
the reaction shown below was used.
result
519
prepared
confirm the unique spectrmn
of
of in this
salt.
Li%~N~F 4 in H20:
LiTCN~F 4 exhibits
temperature independent g-
values and spectral lineshape. The g-values and, Li+TCN(~4 - + M+CI - -.... > M+~L-%~4 - + Li + + Cl-.
hence,
the
lineshape
are
symmetric.
The
spectral envelope is rather narrow (i.e. ca All
the alkali-metal T C N ~ 4 1:1 salts
were
obtained
navy blue microcrystals with the exception
G).
magnetic susceptibility obeys Curie law. The
of NaTCNQF 4 which exhibits a purple color in the microcrystalline state. UV-visible measurements were done on ACTA MVI. All
the
Varian
ESR spectrometer equipped
cavity
and
a
dual
channel
g-values
temperature
dependence
in g-value,
magnetic
susceptibility, envelope.
spectra
a
isomorphous,
The
Integration of the spectra for NaTCN~F 4 was done
temperature change
UV-visible to
measurements
were
done
investigate the stoichiometry of
phase
differential
scanning
in the
for
Rb
very strong absorbance at 385 nm and
absorbance
at
364 rim.
All the
and
alkali
metal 415,
C ~
4
the difference in alkali metals.
exhibits
The spectra of
4 are in good agreement
species
of
g-value
suspected
versus
an a
abrupt possible
transition.
However,
calorimetry and magnetic
The magnetic
susceptibility
with activation
suggests
activated. be
and L i ~
energies
0.04
temperature
that this salt is
thermally
eV. a
CSTCNGF 4
spectral
unique
monotonic
above
110
K.
linewidth
decrease Below
with the reported spectra 6'7 . The ratio between A756/A85 $ = 0 . 4 and A415/A85 $ = 1 . 2 f o r a l l
phenomenon is reflected in the g-values.
salts
including both Rb and
Cs
the
salts.
of
The activation energy is measured to
temperature, the linewidth stays constant.
TCN~ 4
are
The relative magnetic susceptibility study of
756, and 858 nm with rather s~all shifts due to ~ 4
the
data suggests both salts are thermally activated
another
TCNGF 4 salts exhibit strong absorbances at
both
We
phase transition.
0.05 eV.
a
they
both salts exhibit
structural
TCN(~ 4 . The spectr~ of neutral TCN~F 4 exhibits
particularly,
for
150 K.
magnetic
salts,
suspect
graphs
at
Cs
TCNQF 4
relative
and linewidth of
We
same
susceptibility studies indicate no evidence of a
3.1. UV-Visible measurements The
the
and powder diffraction studies are
underw~ly.
by I ~ PC-XT.
order
T C N ~ 4 are
They exhibit
a
3. RESULTS
both K and Rb
dependent.
on
recorder.
of
temperature
with
ESR measurements were performed E-12
dual
Beckman
Acetonitrile was used as the solvent.
0.6
The temperature dependence of the relative
with that This
NaTCN~F 4 exhibits a complex spectral envelope
M.T. Jones et al. / ESR studies o f the polycrystalline alkali metal
520
at room t ~ r a t u r e The
spectral
compared to the other salts.
envelope of this salt at
various
metal
TCNQ
and
TCNQF 4
explanations of the are
magnetic species.
This is further supported by
susceptibility of the cesium
the
magnetic
and
study
of the
dence
The study of the
of
the
magnetic
susceptibility
of
temperature depen-
susceptibility reveals
that from room temperature to 231 K,
spectral
t~rature
changes into a much slower
The
authors
measurements.
activation
energy
is dominant, while in the low temperthe
salt is
salts
magnetic activated
increases
with
0.6 G at 110 K to
ACKNOWL~X~'fS
the species with the
ature region,
The
4.5 G at 298 K).
Megh
larger
KTCN~ 4
2.
linewidth
(i.e. from ca
rate. Therefore, in the high temperature region,
(0.13 eV)
reference
Detailed
there is a
very sharp decrease of the intensity, then below 231 K, the decrement
the
in
behavior of
temperatures suggests the presence of two unique
NaTCN(~ 4.
discussed
series.
spectrum is dominated by the
Singh for
would like to
acknowledge
assistance with the Also,
Dr.
UV-visible
Dr. Geoff Ashwell for the
differential
scanning
KTCNF 4 .
of the authors (TM) acknowledges
One
calorimetry
study
of
Dr. Shelly Kumar and the department of Chemistry
lower activation energy species (0.03 eV).
at University of Missouri-St. Louis for the 1985 Summer Fellowship.
4. DISCUSSION AhD CONCLUSIONS There
are
properties
considerable
variations
in
for these alkali metal ~ 4
salts
with the exception of the K and Rb salts. may
be
due
structure
to the difference in
of the salts.
the
crystal
In the case of
one can assume the position of the metal to
be
hand,
near the cyanide groups. because
negative one
of
the
additional
located
at
cation
the various positions
other
distributed
can assume the alkali metal cation
atoms, may
be
relative
to
the Tt-~QP4 anion radical (See reference 1). This fact
and
large
the size of the cation may result
differences
structure differences
of
in
these in
the
the
salts,
in
microcrystalline and
magnetic
consequently,
properties
as
salt exhibits Curie law in
the
demonstrated as above. The
lithium
magnetic susceptibility. which
i.R. D. Rataiczak, M. T. Jones, J. R. Reeder, and D. J. Sandman, Mol. Phys. 56 (1985) 65.
TCNQ,
On the
charge density on the fluorine
REF~ES
This
2. M.
T. Jones, S. Jansen, A. Berndt, S. Puloka, R. D. Rataiczak, and D. J. Sandman, in preparation.
3. For a preliminary report, see M. T. Jones, T.
Maruo, S. Jansen, J. Roble, and R. D. Rataiczak, Mol. Cryst. Liq. Cryst. 134 (1986) 21. 4. a)
E. L. Martin, U.S. Patent 3,558,671, January 26, 1971; b) R. C. Wheland and E. L. Martin, J. Org. Chem. 40 (1975) 310.
5. R.
L. Melby, R. J. Harder, W. R. Hertler, W. R. Mahler, R. E. Benson, and W. E. Mochel, J. Am. Chem. Soc, 84 (1962) 3374.
6. J.
B. Torrance, J. J. Mayerle, K. Bechgaard, B. D. Silverman, and Y. Tomkiewicz, Phys. Rev. B. 22 (1980) 4960.
This is the only salt
is not themrelly activated in the
alkali
7. I. Zanon and C. (1983) 3657.
Pecile,
J.
Phys. Chem. 87
5]8
COMPARATIVE ESR ST[DIES OF THE POLYCRYSTALLINE ~(TCNQF 4) CHAR(~ TRANSFER SALTS
AI/KALI METAL
TETRAFLUORC/I~.'rKACYAND(~INODI-
M. Thomas Jones, Toshio Maruo, Susan Jansen*, James Roble, and Raymond D. Rataiczak'* Department of Chemistry,
University of Missouri-St.
Louis,
St. Louis, Mo. 63121, USA;
The entire series of alkali metal charge transfer salts of tetrafluorotetracyanoquinodimethan(TC~(~,) have been synthesized and studied by electron spin resonance(ESR) techniques. The tenperature 4dependence of the g-tensor, the temperature dependence of the relative magnetic susceptibility and the temperature dependence of the spectral envelope of each salt is discussed. The spectral properties of these salts are discussed in terms of the relationship between the size, electropesitivity, and other physical properties of the alkali metal ion as one moves through the alkali metal series. The lithium salt exhibits a temperature independent g-tensor and the magnetic susceptibility follows Curie Law from 77 to 300 K. The ESR envelope of the sodium salt consists of two overlapping spectra. The magnetic susceptibility of both species is thermally activated. The spectral envelopes of the potassium and rubidium salts are similar in shape and behavior. Both are strongly dependent upon temperature. Their magnetic susceptibilities are thermally activated. The potassium salt has been studied from ca 4 to 300 K. An abrupt change in the spectral lineshapes of the potassium and rubidium salts is observed at ca 150 K. Finally, the spectral envelope of the cesium salt displays a unique monotonic decrease in linewidth with temperature. able to grow single crystals of this salt in our
1. I ~ D t L - T I O N
Our
laboratory
magnetic salts
has
been
investigating
properties of various charge
and complexes of TCNQ and ~ 4
Studies
of
solutions of KTCNQ and
laboratories.
suspect
growing initiated
is
due
to
of
distributed electronegativity of TCN(~ 4 . We have
in
crystal
difficulty
transfer
KTCNQF 4
single
the
by
ESR.
a
We
the studies of the series of
metal
form ion pairs.
cation size and its electropositivity may effect
pairs
However, the structures for the
are
different
due
to
the
difference in the electronegativity of relative
to
hydrogen I .
polycrystalline show
samples
t_hat they
crystal
do
not
structures 2 .
Studies
of KTCNQ possess The
large
fluorine
solid
and
of
since the changes in
the micro-crystalline structure and of
single
obtained
crystals.
However,
The
isomorphous F~R
ESR
studies
of
the
to
whereas
~ 4
display
growth
have
not salts
asymmetric
demonstrate the effect of the differences in
line shapes and show considerable variation with
interaction
temperature.
structures of these salts.
In particular, an abrupt change in
polycrystalline
alkali-metal TCNQF 4 I: I salts 3 are reported here cation size, electropositivity,
of
the
single crystals of any of these
spectra of KTCNQ exhibit symmetrical line shapes those
we
the
yet.
~ 4
state
salts,
alkali-
ether type solvents indicate both anion radicals ion
TCNQF 4
the
energy
upon
the
and spin orbit microcrystalline
linewidth is observed at 150 K. A has
single crystal X-ray structure of not been reported,
yet.
KTCNQF 4
Nor have we
been
2. EXPERIMI~AL
TCNQF 4 was synthesized at the University
*Present address: Department of Chemistry, Cornell University, Ithaca, New York 14853, USA. **Department of Chemistry, Muskingtln College, New Concord, ohio 43762, USA. 0378 - 4 3 6 3 / 8 6 / $ 0 3 . 5 0 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division) and Y a m a d a Science F o u n d a t i o n
of
M.T. Jones et al. / ESR studies o f the polycrystalline alkali metal Missouri-St.
Louis and Musking~n College 4.
alkali-metal
simple salts were
the
for
methods
preparation
simple salts of TCNQ 5 . ~ 4 '
Its
synthesized of
Thus,
by
This
for Li,
The
room
salts
have
the
> 2M~-~qQP4 - + M+ + 13-
Rb
and
Cs 1:1 salts
were
prepared
from
the
ESR
of polycrystalline been
alkali-metal
order
spectra
studied
Several
and
the
TCNQF 4
there
are
NaTCN(~ 4 and
different
samples
salts were independently
to
of
alkali-metal
differences between
others.
NaTCN~" 4 The
temperature
series
considerable
3M+I - + 2TCSEF 4 . . . . . .
that all
3.2. ESR measurements
Na, and
CH3CN
shows
TCSEF 4 prepared are 1:1 simple salts.
alkali-metal
the reaction shown below was used.
result
519
prepared
confirm the unique spectrmn
of
of in this
salt.
Li%~N~F 4 in H20:
LiTCN~F 4 exhibits
temperature independent g-
values and spectral lineshape. The g-values and, Li+TCN(~4 - + M+CI - -.... > M+~L-%~4 - + Li + + Cl-.
hence,
the
lineshape
are
symmetric.
The
spectral envelope is rather narrow (i.e. ca All
the alkali-metal T C N ~ 4 1:1 salts
were
obtained
navy blue microcrystals with the exception
G).
magnetic susceptibility obeys Curie law. The
of NaTCNQF 4 which exhibits a purple color in the microcrystalline state. UV-visible measurements were done on ACTA MVI. All
the
Varian
ESR spectrometer equipped
cavity
and
a
dual
channel
g-values
temperature
dependence
in g-value,
magnetic
susceptibility, envelope.
spectra
a
isomorphous,
The
Integration of the spectra for NaTCN~F 4 was done
temperature change
UV-visible to
measurements
were
done
investigate the stoichiometry of
phase
differential
scanning
in the
for
Rb
very strong absorbance at 385 nm and
absorbance
at
364 rim.
All the
and
alkali
metal 415,
C ~
4
the difference in alkali metals.
exhibits
The spectra of
4 are in good agreement
species
of
g-value
suspected
versus
an a
abrupt possible
transition.
However,
calorimetry and magnetic
The magnetic
susceptibility
with activation
suggests
activated. be
and L i ~
energies
0.04
temperature
that this salt is
thermally
eV. a
CSTCNGF 4
spectral
unique
monotonic
above
110
K.
linewidth
decrease Below
with the reported spectra 6'7 . The ratio between A756/A85 $ = 0 . 4 and A415/A85 $ = 1 . 2 f o r a l l
phenomenon is reflected in the g-values.
salts
including both Rb and
Cs
the
salts.
of
The activation energy is measured to
temperature, the linewidth stays constant.
TCN~ 4
are
The relative magnetic susceptibility study of
756, and 858 nm with rather s~all shifts due to ~ 4
the
data suggests both salts are thermally activated
another
TCNGF 4 salts exhibit strong absorbances at
both
We
phase transition.
0.05 eV.
a
they
both salts exhibit
structural
TCN(~ 4 . The spectr~ of neutral TCN~F 4 exhibits
particularly,
for
150 K.
magnetic
salts,
suspect
graphs
at
Cs
TCNQF 4
relative
and linewidth of
We
same
susceptibility studies indicate no evidence of a
3.1. UV-Visible measurements The
the
and powder diffraction studies are
underw~ly.
by I ~ PC-XT.
order
T C N ~ 4 are
They exhibit
a
3. RESULTS
both K and Rb
dependent.
on
recorder.
of
temperature
with
ESR measurements were performed E-12
dual
Beckman
Acetonitrile was used as the solvent.
0.6
The temperature dependence of the relative
with that This
NaTCN~F 4 exhibits a complex spectral envelope
M.T. Jones et al. / ESR studies o f the polycrystalline alkali metal
520
at room t ~ r a t u r e The
spectral
compared to the other salts.
envelope of this salt at
various
metal
TCNQ
and
TCNQF 4
explanations of the are
magnetic species.
This is further supported by
susceptibility of the cesium
the
magnetic
and
study
of the
dence
The study of the
of
the
magnetic
susceptibility
of
temperature depen-
susceptibility reveals
that from room temperature to 231 K,
spectral
t~rature
changes into a much slower
The
authors
measurements.
activation
energy
is dominant, while in the low temperthe
salt is
salts
magnetic activated
increases
with
0.6 G at 110 K to
ACKNOWL~X~'fS
the species with the
ature region,
The
4.5 G at 298 K).
Megh
larger
KTCN~ 4
2.
linewidth
(i.e. from ca
rate. Therefore, in the high temperature region,
(0.13 eV)
reference
Detailed
there is a
very sharp decrease of the intensity, then below 231 K, the decrement
the
in
behavior of
temperatures suggests the presence of two unique
NaTCN(~ 4.
discussed
series.
spectrum is dominated by the
Singh for
would like to
acknowledge
assistance with the Also,
Dr.
UV-visible
Dr. Geoff Ashwell for the
differential
scanning
KTCNF 4 .
of the authors (TM) acknowledges
One
calorimetry
study
of
Dr. Shelly Kumar and the department of Chemistry
lower activation energy species (0.03 eV).
at University of Missouri-St. Louis for the 1985 Summer Fellowship.
4. DISCUSSION AhD CONCLUSIONS There
are
properties
considerable
variations
in
for these alkali metal ~ 4
salts
with the exception of the K and Rb salts. may
be
due
structure
to the difference in
of the salts.
the
crystal
In the case of
one can assume the position of the metal to
be
hand,
near the cyanide groups. because
negative one
of
the
additional
located
at
cation
the various positions
other
distributed
can assume the alkali metal cation
atoms, may
be
relative
to
the Tt-~QP4 anion radical (See reference 1). This fact
and
large
the size of the cation may result
differences
structure differences
of
in
these in
the
the
salts,
in
microcrystalline and
magnetic
consequently,
properties
as
salt exhibits Curie law in
the
demonstrated as above. The
lithium
magnetic susceptibility. which
i.R. D. Rataiczak, M. T. Jones, J. R. Reeder, and D. J. Sandman, Mol. Phys. 56 (1985) 65.
TCNQ,
On the
charge density on the fluorine
REF~ES
This
2. M.
T. Jones, S. Jansen, A. Berndt, S. Puloka, R. D. Rataiczak, and D. J. Sandman, in preparation.
3. For a preliminary report, see M. T. Jones, T.
Maruo, S. Jansen, J. Roble, and R. D. Rataiczak, Mol. Cryst. Liq. Cryst. 134 (1986) 21. 4. a)
E. L. Martin, U.S. Patent 3,558,671, January 26, 1971; b) R. C. Wheland and E. L. Martin, J. Org. Chem. 40 (1975) 310.
5. R.
L. Melby, R. J. Harder, W. R. Hertler, W. R. Mahler, R. E. Benson, and W. E. Mochel, J. Am. Chem. Soc, 84 (1962) 3374.
6. J.
B. Torrance, J. J. Mayerle, K. Bechgaard, B. D. Silverman, and Y. Tomkiewicz, Phys. Rev. B. 22 (1980) 4960.
This is the only salt
is not themrelly activated in the
alkali
7. I. Zanon and C. (1983) 3657.
Pecile,
J.
Phys. Chem. 87