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(TMTSF)2ClO4 in the extreme quantum limit
SvntheticMetals, 27 (1988) B41 B48
1341
(TMTSF)2CIO 4 IN THE EXTREME QUANTUM LIMIT
R.V.
Chamberlin, (I) M.J. Naughton, (2) X. Yan, (2) L.Y. Chiang, (3)
S.-Y.
Hsu, (2,3) and P.M. Chaikin (2,3,4)
(1)Department of Physics, Arizona State University, Tempe, AZ 85287
(U.S.A
(2)Department of Physics, Philadelphia,
PA 19104
University of Pennsylvania, (U.S.A.)
(3)Exxon Research and Englneering Co., Annandale,
NJ 08801
(U.S.A.)
(4)Department of Physics, Princeton,
NJ 08540
Princeton University,
(U.S.A.)
ABSTRACT Magnetotransport
and m a g n e t i z a t i o n measurements on (TMTSF)2CIO 4
in fields up to 31 T reveal an e x t r a o r d i n a r i l y stable semimetallic state, with a constant filling factor
(~),
from 8 to 27 T.
The
relative Hall value and energy gap of this state suggest that it is related to the ~=i/3 fractional quantum Hall effect. there
At 27 T
is a new transition to a compensated semiconducting phase.
After a brief properties
review of the "low-field" behavior,
we discuss the
of these novel high-field phases.
INTRODUCTION The B e c h g a a r d family I of charge-transfer where x=ClO4,
salts
[(TMTSF)2X;
PF 6, ReO 4, etc.] are highly anisotropic
organic
conductors which exhibit a rich variety of ground states characteristic
of quasi 2-dimensional electronic
systems.
interest has been in the field-induced s p i n - d e n s i t y - w a v e transitions resistance
in these materials. 2 (Pxx), Hall
measurements "low-field" stable
(SDW)
We have made 3 longitudinal
resistance
(Pxy), and m a g n e t i z a t i o n
on (TMTSF)2CIO 4 in fields up to 31T. SDW transition,
Recent
After
the final
(TMTSF)2CIO 4 remains in a remarkably
state from 8 T to 27 T, where there is a new t r a n s i t i o n to
a v e r y - h i g h field behavior
(VHF) phase.
Here we here we will
focus on the
in these high-field phases.
0379-6779/88/$3.50
© Elsevier Sequoia/Printed in The Netherlands
B42
BACKGROUND
The (TMTSF)2CIO 4 crystal consists of rectangular TMTSF molecules
stacked along the a axis.
The s t o i c h i o m e t r y and
structure of the crystal yield a conduction electron density of ~1021/cm 3 with an approximate bandwidth ratio of 100:10:<1 a:b*:c* directions.
The purity of a particular
in the
(TMTSF)2CIO 4
sample depends on how rapidly it is cooled through a structural phase transition near 24K;
high quality,
slow cooled,
samples may
have mean-free paths in excess of 10~m.
For magnetic
H>2-3T applied normal
electron motion in the c*
to the a-b* plane,
fields
d i r e c t i o n becomes negligible and (TMTSF)2CIO 4 becomes quasi-2D. M a g n e t o t r a n s p o r t measurements a series of steps and plateaus
in fields up to 20T (Fig. i) show
in Pxy, somewhat
q u a n t u m Hall effect, 4 but several from the usual QHE. not integral
Briefly,
the values of the Pxy plateaus are
fractions of h/e 2 (25.8...kQ/layer),
sharply during the first few plateaus, in l/H,
reminiscent of the
features 5,6 d i s t i n g u i s h this Pxx increases
the steps are not p e r i o d i c
the fields at which the steps occur
(as well as the
numbers and types of steps) are sample purity and temperature dependent,
and there is distinct hysteresis between the up- and
d o w n - f i e l d sweeps.
M a g n e t i z a t i o n 7 and specific heat 8 m e a s u r e m e n t s
show that the Hall steps are in fact due to a cascade of t h e r m o d y n a m i c phase transitions. Several theories 9-13 have been developed which give good, least qualitative, 2.4
"~-
i
~
i
u n d e r s t a n d i n g of these transitions. E
1
l
r
at
The Fermi
1--24
1.6
16
t
c~x 0 . 0
-0.11~
0
t
I
4
I tJ
1
I
13
l
1:'
I
J
1
16
~('r) Fig. i. Hall (dashed) and longitudinal (solid) resistivities for (TMTSF)2CIO 4 at 0.7 K. A brief shoulder at 7.5 T coincides with a sharp reduction in PxxThe ratio of Pxy from this shoulder to the high-field plateau is 1:(2.96±0.05).
B43 surface consists of two warped planes about ka-±K/2a. (TMTSF)2CIO 4 is highly anisotropic,
the b* bandwidth
Although in pure
samples at low fields is sufficient to suppress the usual instabilities,
and the system is an open-orbit metal.
applied parallel
ID
For H
to c*, net electron motion is along the a axis
with o s c i l l a t o r y motion in the b* direction. the b* oscillations decrease, (Hth=4.5T at 0.7K) s p i n - d e n s i t y wave.
With increasing H,
until at the threshold field
the system becomes unstable
to formation of a
The theories consider the field d e p e n d e n c e
of
the particular nesting vector which gives the maximum c o n d e n s a t i o n energy.
Transitions occur when a new distortion becomes
and the system d i s c o n t i n u o u s l y transitions,
readjusts the SDW.
favorable
Between
minor adjustments maintain the lowest total energy.
A l t h o u g h E F is pinned
in a gap,
impurities and the u n d e r l y i n g open-
orbit 3D nature of this system lead to nonlocalized gap states. Thus,
neither Laughlin criterion 14 of a mobility gap nor a field
recurrent energy is met.
Nevertheless,
the adjustments which
m a i n t a i n the lowest energy provide ostensibly constant Landau filling
(~) at nonquantized values of Pxy"
Incomplete nesting of the self-consistent SDW potential pockets of electrons and holes, carriers.
In moderate
fields,
leaves
but greatly reduces the number
of
a typical sample of (TMTSF)2CIO 4 may
contain more than 105 layers of high-mobility,
quasi
2-D electrons,
with a carrier density of about 1011/cm 2. EXTREME QUANTUM LIMIT The existing theories all predict that E F should go to the single
remaining large gap at a final transition
(usually taken to
be the one near 8 T), above which the system should become insulating.
Figure 2 shows that, at 0.7 K,
semimetallic
from 8 to 27 T.
Furthermore,
(TMTSF)2CIO 4 remains the fact that
Pxy is
constant shows that the carrier density is changed in such a way as to m a i n t a i n a fixed Landau filling over this entire Insight into the origin of this unpredicted, stable
range.
extraordinarily
state comes from the relative values of Pxy-
A recent
theory 15 has shown that impurity scattering and magnetic b r e a k d o w n will
reduce the magnitude of Pxy, but since these effects are
s u b s t a n t i a l l y constant, remain quantized.
the ratio between successive plateaus will
Thus one expects
ratios of 1/3:1/2:1
steps p r e c e d i n g the final transition. temperatures, these
ratios.
Indeed,
for the 3
at very low
Ribault 16 has found that the plateaus do scale with Furthermore he finds that the ratio of the 8 T step
B44
is 1:2.9.
We have
measured numerous
2
samples and find that the magnitude of the high-field plateau may
7
range from 6 to 18 kQ/layer,
whereas
the
ratio of the 8 T Hall step is i n v a r i a b l y 1:(2.96±0.05).
The
combination of constant Pxy with this u n i v e r s a l
| i
li ,
" I ~ c LI!
F
step size strongly suggests
that the
carriers are in a
:i-
fractional q u a n t u m Hall effect 17 state with
0
8
16
24
32
9=i/3.
H(T)
It should be
emphasized,
Fig. 2. Hall (dashed) and longitudinal (solid) resistivities at 0.7 K in fields up to 31 T. The high-field plateau persists out to 27.1±0.1 T where a sharp decrease in Pxy and dramatic increase in Pxx (note logarithmic scale) define the VHF transition.
not expected,
I
I
I
I
I
I
I
I
(TMTSF)2CIO 4 has neither nor fixed EF; it has the freedom to
adjust a SDW d i s t o r t i o n
I
to m a i n t a i n
"L"
the lowest
total energy.
:~ 10
Further evidence
for
a fractionally quantized
I
[] "~ .N ~4
FQHE is
since
a fixed carrier d e n s i t y additional
100
however,
that the "usual"
state comes from the
1
energy gap for resistive excitations. 25 T
A semilog
plot of Pxx vs.
~'~.
ckO.1
inverse
temperature at 25 T I
0
i
}
j
i
i
I
0.5 ]/TEMP. (K - 1 )
i
(crosses in Fig.
I
1.0
Fig. 3. Semilog plot of longitudinal resistance as a function of inverse temperature. The best fits to the data (solid lines) give activation energies of 6.0±0.5 K at 25 T and 4±1 K at 29 T.
3)
shows an a c t i v a t i o n energy of 6.0±0.5 K, which is about an order of magnitude
less than
the cyclotron energy.
B45
A l t h o u g h 6 K corresponds to a p a i r - c r e a t i o n energy of about twice that found for the 1/3 FQHE state in the h i g h e s t - p u r i t y s e m i c o n d u c t i n g devices, 18 quantitative
comparison may be
m e a n i n g l e s s because of the vastly different systems. do show,
however,
that the resistive excitations
i m m e d i a t e l y preceeding with ~ i )
the 8 T transition
Figs.
1 and 2
in the state
(presumably a s s o c i a t e d
have a significantly higher barrier;
suggesting that the
s t a b i l i t y of the 8 to 27 T state cannot be explained by a singlee l e c t r o n energy gap. Independent
support for the fixed Landau filling and extreme
stability of the state from 8 to 27 T comes from the m a g n e t i z a t i o n measurements,
Fig.
a paramagnetic paramagnetic
4.
jump,
The "low-field"
transitions are signalled by
followed by a diamagnetic
recovery.
The
steps at higher fields can be ascribed to de H a a s - v a n
A l p h e n oscillations
from quantized edge states, 19 and are not
a s s o c i a t e d with any phase transitions. 20 oscillations
Removing these
reveals that the intrinsic m a g n e t i z a t i o n d e c r e a s e s
linearly from 8 until 18 T, where it saturates to a negative value. A linear diamagnetic filling,
term is most
readily related to a fixed Landau
for which the net energy increases as H 2, p r o d u c i n g a
m a g n e t i z a t i o n which decreases linearly with field. 21
Even though
the net orbital magnetic energy in (TMTSF)2CIO 4 (dashed curve
in
3) becomes positive above ~22 T, 22 the ~=i/3 state persists
Fig. until
27 T.
Several transition 40
Finally
(TMTSF)2CIO 4 must find a new ground state.
features distinguish
the very high-field
(VHF)
from the cascade of low-field transitions.
I
I
I
1
I
80
I
/i/
20
First,
40
.~
o v
-20
-40
"\\
I
8
I
/i
~
I
16
1
,
1
24
I
-40 I
3~ 8o
Fig. 4. M a g n e t i z a t i o n of (TMTSF)2CIO 4 at 0.7 K (points). Fourier filtered data (solid) showing the intrinsic h i g h - f i e l d behavior. The magnetic energy (EM=;M'dH, dashed) becomes positive above ~22 T
B46 Pxxincreases dramatically, 30 T at 0.7K. 28 T.
Second,
Third,
nearly 3 orders of magnitude
Pxy decreases sharply,
from 25 to
to 0±5 k~/layer above
the VHF transition has a negative
field slope;
the
field at which it occurs decreases with increasing temperature. Finally there is no conspicuous paramagnetic anomaly a s s o c i a t e d with the VHF transition.
Recently
(TMTSF)2CIO 4 has been found to
be reentrant, 23 implying that the VHF behavior
is independent of
all the field-induced SDW phases.
Nevertheless,
a c t i v a t e d behavior
3) with an energy gap of 4±1 K.
Hence,
metallic
(pluses in Fig.
at 29 T,
Pxx shows
(TMTSF)2CIO 4 can be made s e m i c o n d u c t i n g without
crossing any obvious transition lines. A possible m e c h a n i s m for the VHF state might be strong I-D localization due to the enhanced anisotropy of the electrons these
fields.
in
An alternative explanation could be a subtle onset
of some type of c h a r g e - d e n s i t y wave. 24
Very recent m e a s u r e m e n t s 25
have shown a threshold electric field for depinning the carriers the VHF state.
in
Wigner 26 localization in very-high fields is
p r e d i c t e d to be weakly first order, 27 with saturated diamagnetism, 28 and is expected to become e n e r g e t i c a l l y
favorable
to a Laughlin liquid at a phase boundary with a negative slope; 29 consistent with what is observed. are necessary, localization
however,
field
Additional measurements
before the precise nature of the electron
in the VHF state can be established.
Existing theories
for the behavior of (TMTSF)2CIO 4 have not
considered the direct Coulomb interactions between electrons. M a n y - b o d y interactions are essential Laughlin
liquid,
mechanisms.
for the formation of the
and for the majority of electron l o c a l i z a t i o n
Their neglect may explain why the ~=i/3 state
from 8
to 27 T and the VHF state above 27 T were unpredicted. CONCLUSIONS High field m a g n e t o t r a n s p o r t and m a g n e t i z a t i o n m e a s u r e m e n t s (TMTSF)2CIO 4 reveal an e x t r a o r d i n a r i l y stable semimetallic with constant Landau filling,
from 8 to 27 T.
on
state,
The ratio of the
Hall
steps preceeding this state and its relatively small energy
gap,
strongly suggest that it is related to the ~=i/3 fractional
q u a n t u m Hall effect. independent
The m a g n e t i z a t i o n measurements provide
support for the stability of this phase,
and also
indicate why the system must eventually find another ground state. At 27 T there is a new transition to a novel with a relatively small Hall
resistivity,
semiconducting
and a saturated
state,
B47
diamagnetism.
The behavior of this v e r y - h i g h - f i e l d phase
indicative of strongly localized electrons, without
is
yet it can be a c c e s s e d
crossing any obvious phase boundaries.
These m e a s u r e m e n t s
show that the high-field behavior of (TMTSF)2CIO 4 remains an interesting experimental and theoretical
challenge.
ACKNOWLEDGEMENTS This
research was supported by an ASU Research
(R.V.C.) (M.J.N.
and National
Incentive Grant
Science Foundation Grant No. DMR8514825
and P.M.C.).
We would like to acknowledge
the assistance
of the staff at the National Magnet Laboratory,
e s p e c i a l l y B.L.
Brandt,
c o n v e r s a t i o n s with
J.S.
Brooks,
M. Ya Azbel,
M.J.
and L.G. Rubin,
Burns,
and useful
P.K. Lam, and J.E. Northrup.
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2495.
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Phys. Rev. A 39 (1986) 1392,
Per
and Phys.
Lett. A 117 (1986) 92. 13 A. Virosztek,
L. Chen, and K. Maki,
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3371. 14 R.B.
Laughlin,
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119
155, Plenum, New York,
59
(1985) 91, and in
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H.L.
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show that E M becomes positive
1799.
Gossard,
and
is s e n s i t i v e l y
In Fig.
fit to this background has been subtracted.
582.
Chiang,
423.
field at which E M becomes positive
dependent upon a small background
59 (1987)
Hsu, L.Y.
4, the best
Alternative
fits
somewhere between 17 and 27 T,
but this does not significantly alter the features in Fig.
4
nor our arguments concerning E M23 M.J. Naughton, M. Ya Azbel, 24 H. Fukuyama, (1979)
25 N. T o y o t a , 34
and P.M. Chaikin, P.M. Platzman,
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397.
102A
(1980)
1341
(TMTSF)2CIO 4 IN THE EXTREME QUANTUM LIMIT
R.V.
Chamberlin, (I) M.J. Naughton, (2) X. Yan, (2) L.Y. Chiang, (3)
S.-Y.
Hsu, (2,3) and P.M. Chaikin (2,3,4)
(1)Department of Physics, Arizona State University, Tempe, AZ 85287
(U.S.A
(2)Department of Physics, Philadelphia,
PA 19104
University of Pennsylvania, (U.S.A.)
(3)Exxon Research and Englneering Co., Annandale,
NJ 08801
(U.S.A.)
(4)Department of Physics, Princeton,
NJ 08540
Princeton University,
(U.S.A.)
ABSTRACT Magnetotransport
and m a g n e t i z a t i o n measurements on (TMTSF)2CIO 4
in fields up to 31 T reveal an e x t r a o r d i n a r i l y stable semimetallic state, with a constant filling factor
(~),
from 8 to 27 T.
The
relative Hall value and energy gap of this state suggest that it is related to the ~=i/3 fractional quantum Hall effect. there
At 27 T
is a new transition to a compensated semiconducting phase.
After a brief properties
review of the "low-field" behavior,
we discuss the
of these novel high-field phases.
INTRODUCTION The B e c h g a a r d family I of charge-transfer where x=ClO4,
salts
[(TMTSF)2X;
PF 6, ReO 4, etc.] are highly anisotropic
organic
conductors which exhibit a rich variety of ground states characteristic
of quasi 2-dimensional electronic
systems.
interest has been in the field-induced s p i n - d e n s i t y - w a v e transitions resistance
in these materials. 2 (Pxx), Hall
measurements "low-field" stable
(SDW)
We have made 3 longitudinal
resistance
(Pxy), and m a g n e t i z a t i o n
on (TMTSF)2CIO 4 in fields up to 31T. SDW transition,
Recent
After
the final
(TMTSF)2CIO 4 remains in a remarkably
state from 8 T to 27 T, where there is a new t r a n s i t i o n to
a v e r y - h i g h field behavior
(VHF) phase.
Here we here we will
focus on the
in these high-field phases.
0379-6779/88/$3.50
© Elsevier Sequoia/Printed in The Netherlands
B42
BACKGROUND
The (TMTSF)2CIO 4 crystal consists of rectangular TMTSF molecules
stacked along the a axis.
The s t o i c h i o m e t r y and
structure of the crystal yield a conduction electron density of ~1021/cm 3 with an approximate bandwidth ratio of 100:10:<1 a:b*:c* directions.
The purity of a particular
in the
(TMTSF)2CIO 4
sample depends on how rapidly it is cooled through a structural phase transition near 24K;
high quality,
slow cooled,
samples may
have mean-free paths in excess of 10~m.
For magnetic
H>2-3T applied normal
electron motion in the c*
to the a-b* plane,
fields
d i r e c t i o n becomes negligible and (TMTSF)2CIO 4 becomes quasi-2D. M a g n e t o t r a n s p o r t measurements a series of steps and plateaus
in fields up to 20T (Fig. i) show
in Pxy, somewhat
q u a n t u m Hall effect, 4 but several from the usual QHE. not integral
Briefly,
the values of the Pxy plateaus are
fractions of h/e 2 (25.8...kQ/layer),
sharply during the first few plateaus, in l/H,
reminiscent of the
features 5,6 d i s t i n g u i s h this Pxx increases
the steps are not p e r i o d i c
the fields at which the steps occur
(as well as the
numbers and types of steps) are sample purity and temperature dependent,
and there is distinct hysteresis between the up- and
d o w n - f i e l d sweeps.
M a g n e t i z a t i o n 7 and specific heat 8 m e a s u r e m e n t s
show that the Hall steps are in fact due to a cascade of t h e r m o d y n a m i c phase transitions. Several theories 9-13 have been developed which give good, least qualitative, 2.4
"~-
i
~
i
u n d e r s t a n d i n g of these transitions. E
1
l
r
at
The Fermi
1--24
1.6
16
t
c~x 0 . 0
-0.11~
0
t
I
4
I tJ
1
I
13
l
1:'
I
J
1
16
~('r) Fig. i. Hall (dashed) and longitudinal (solid) resistivities for (TMTSF)2CIO 4 at 0.7 K. A brief shoulder at 7.5 T coincides with a sharp reduction in PxxThe ratio of Pxy from this shoulder to the high-field plateau is 1:(2.96±0.05).
B43 surface consists of two warped planes about ka-±K/2a. (TMTSF)2CIO 4 is highly anisotropic,
the b* bandwidth
Although in pure
samples at low fields is sufficient to suppress the usual instabilities,
and the system is an open-orbit metal.
applied parallel
ID
For H
to c*, net electron motion is along the a axis
with o s c i l l a t o r y motion in the b* direction. the b* oscillations decrease, (Hth=4.5T at 0.7K) s p i n - d e n s i t y wave.
With increasing H,
until at the threshold field
the system becomes unstable
to formation of a
The theories consider the field d e p e n d e n c e
of
the particular nesting vector which gives the maximum c o n d e n s a t i o n energy.
Transitions occur when a new distortion becomes
and the system d i s c o n t i n u o u s l y transitions,
readjusts the SDW.
favorable
Between
minor adjustments maintain the lowest total energy.
A l t h o u g h E F is pinned
in a gap,
impurities and the u n d e r l y i n g open-
orbit 3D nature of this system lead to nonlocalized gap states. Thus,
neither Laughlin criterion 14 of a mobility gap nor a field
recurrent energy is met.
Nevertheless,
the adjustments which
m a i n t a i n the lowest energy provide ostensibly constant Landau filling
(~) at nonquantized values of Pxy"
Incomplete nesting of the self-consistent SDW potential pockets of electrons and holes, carriers.
In moderate
fields,
leaves
but greatly reduces the number
of
a typical sample of (TMTSF)2CIO 4 may
contain more than 105 layers of high-mobility,
quasi
2-D electrons,
with a carrier density of about 1011/cm 2. EXTREME QUANTUM LIMIT The existing theories all predict that E F should go to the single
remaining large gap at a final transition
(usually taken to
be the one near 8 T), above which the system should become insulating.
Figure 2 shows that, at 0.7 K,
semimetallic
from 8 to 27 T.
Furthermore,
(TMTSF)2CIO 4 remains the fact that
Pxy is
constant shows that the carrier density is changed in such a way as to m a i n t a i n a fixed Landau filling over this entire Insight into the origin of this unpredicted, stable
range.
extraordinarily
state comes from the relative values of Pxy-
A recent
theory 15 has shown that impurity scattering and magnetic b r e a k d o w n will
reduce the magnitude of Pxy, but since these effects are
s u b s t a n t i a l l y constant, remain quantized.
the ratio between successive plateaus will
Thus one expects
ratios of 1/3:1/2:1
steps p r e c e d i n g the final transition. temperatures, these
ratios.
Indeed,
for the 3
at very low
Ribault 16 has found that the plateaus do scale with Furthermore he finds that the ratio of the 8 T step
B44
is 1:2.9.
We have
measured numerous
2
samples and find that the magnitude of the high-field plateau may
7
range from 6 to 18 kQ/layer,
whereas
the
ratio of the 8 T Hall step is i n v a r i a b l y 1:(2.96±0.05).
The
combination of constant Pxy with this u n i v e r s a l
| i
li ,
" I ~ c LI!
F
step size strongly suggests
that the
carriers are in a
:i-
fractional q u a n t u m Hall effect 17 state with
0
8
16
24
32
9=i/3.
H(T)
It should be
emphasized,
Fig. 2. Hall (dashed) and longitudinal (solid) resistivities at 0.7 K in fields up to 31 T. The high-field plateau persists out to 27.1±0.1 T where a sharp decrease in Pxy and dramatic increase in Pxx (note logarithmic scale) define the VHF transition.
not expected,
I
I
I
I
I
I
I
I
(TMTSF)2CIO 4 has neither nor fixed EF; it has the freedom to
adjust a SDW d i s t o r t i o n
I
to m a i n t a i n
"L"
the lowest
total energy.
:~ 10
Further evidence
for
a fractionally quantized
I
[] "~ .N ~4
FQHE is
since
a fixed carrier d e n s i t y additional
100
however,
that the "usual"
state comes from the
1
energy gap for resistive excitations. 25 T
A semilog
plot of Pxx vs.
~'~.
ckO.1
inverse
temperature at 25 T I
0
i
}
j
i
i
I
0.5 ]/TEMP. (K - 1 )
i
(crosses in Fig.
I
1.0
Fig. 3. Semilog plot of longitudinal resistance as a function of inverse temperature. The best fits to the data (solid lines) give activation energies of 6.0±0.5 K at 25 T and 4±1 K at 29 T.
3)
shows an a c t i v a t i o n energy of 6.0±0.5 K, which is about an order of magnitude
less than
the cyclotron energy.
B45
A l t h o u g h 6 K corresponds to a p a i r - c r e a t i o n energy of about twice that found for the 1/3 FQHE state in the h i g h e s t - p u r i t y s e m i c o n d u c t i n g devices, 18 quantitative
comparison may be
m e a n i n g l e s s because of the vastly different systems. do show,
however,
that the resistive excitations
i m m e d i a t e l y preceeding with ~ i )
the 8 T transition
Figs.
1 and 2
in the state
(presumably a s s o c i a t e d
have a significantly higher barrier;
suggesting that the
s t a b i l i t y of the 8 to 27 T state cannot be explained by a singlee l e c t r o n energy gap. Independent
support for the fixed Landau filling and extreme
stability of the state from 8 to 27 T comes from the m a g n e t i z a t i o n measurements,
Fig.
a paramagnetic paramagnetic
4.
jump,
The "low-field"
transitions are signalled by
followed by a diamagnetic
recovery.
The
steps at higher fields can be ascribed to de H a a s - v a n
A l p h e n oscillations
from quantized edge states, 19 and are not
a s s o c i a t e d with any phase transitions. 20 oscillations
Removing these
reveals that the intrinsic m a g n e t i z a t i o n d e c r e a s e s
linearly from 8 until 18 T, where it saturates to a negative value. A linear diamagnetic filling,
term is most
readily related to a fixed Landau
for which the net energy increases as H 2, p r o d u c i n g a
m a g n e t i z a t i o n which decreases linearly with field. 21
Even though
the net orbital magnetic energy in (TMTSF)2CIO 4 (dashed curve
in
3) becomes positive above ~22 T, 22 the ~=i/3 state persists
Fig. until
27 T.
Several transition 40
Finally
(TMTSF)2CIO 4 must find a new ground state.
features distinguish
the very high-field
(VHF)
from the cascade of low-field transitions.
I
I
I
1
I
80
I
/i/
20
First,
40
.~
o v
-20
-40
"\\
I
8
I
/i
~
I
16
1
,
1
24
I
-40 I
3~ 8o
Fig. 4. M a g n e t i z a t i o n of (TMTSF)2CIO 4 at 0.7 K (points). Fourier filtered data (solid) showing the intrinsic h i g h - f i e l d behavior. The magnetic energy (EM=;M'dH, dashed) becomes positive above ~22 T
B46 Pxxincreases dramatically, 30 T at 0.7K. 28 T.
Second,
Third,
nearly 3 orders of magnitude
Pxy decreases sharply,
from 25 to
to 0±5 k~/layer above
the VHF transition has a negative
field slope;
the
field at which it occurs decreases with increasing temperature. Finally there is no conspicuous paramagnetic anomaly a s s o c i a t e d with the VHF transition.
Recently
(TMTSF)2CIO 4 has been found to
be reentrant, 23 implying that the VHF behavior
is independent of
all the field-induced SDW phases.
Nevertheless,
a c t i v a t e d behavior
3) with an energy gap of 4±1 K.
Hence,
metallic
(pluses in Fig.
at 29 T,
Pxx shows
(TMTSF)2CIO 4 can be made s e m i c o n d u c t i n g without
crossing any obvious transition lines. A possible m e c h a n i s m for the VHF state might be strong I-D localization due to the enhanced anisotropy of the electrons these
fields.
in
An alternative explanation could be a subtle onset
of some type of c h a r g e - d e n s i t y wave. 24
Very recent m e a s u r e m e n t s 25
have shown a threshold electric field for depinning the carriers the VHF state.
in
Wigner 26 localization in very-high fields is
p r e d i c t e d to be weakly first order, 27 with saturated diamagnetism, 28 and is expected to become e n e r g e t i c a l l y
favorable
to a Laughlin liquid at a phase boundary with a negative slope; 29 consistent with what is observed. are necessary, localization
however,
field
Additional measurements
before the precise nature of the electron
in the VHF state can be established.
Existing theories
for the behavior of (TMTSF)2CIO 4 have not
considered the direct Coulomb interactions between electrons. M a n y - b o d y interactions are essential Laughlin
liquid,
mechanisms.
for the formation of the
and for the majority of electron l o c a l i z a t i o n
Their neglect may explain why the ~=i/3 state
from 8
to 27 T and the VHF state above 27 T were unpredicted. CONCLUSIONS High field m a g n e t o t r a n s p o r t and m a g n e t i z a t i o n m e a s u r e m e n t s (TMTSF)2CIO 4 reveal an e x t r a o r d i n a r i l y stable semimetallic with constant Landau filling,
from 8 to 27 T.
on
state,
The ratio of the
Hall
steps preceeding this state and its relatively small energy
gap,
strongly suggest that it is related to the ~=i/3 fractional
q u a n t u m Hall effect. independent
The m a g n e t i z a t i o n measurements provide
support for the stability of this phase,
and also
indicate why the system must eventually find another ground state. At 27 T there is a new transition to a novel with a relatively small Hall
resistivity,
semiconducting
and a saturated
state,
B47
diamagnetism.
The behavior of this v e r y - h i g h - f i e l d phase
indicative of strongly localized electrons, without
is
yet it can be a c c e s s e d
crossing any obvious phase boundaries.
These m e a s u r e m e n t s
show that the high-field behavior of (TMTSF)2CIO 4 remains an interesting experimental and theoretical
challenge.
ACKNOWLEDGEMENTS This
research was supported by an ASU Research
(R.V.C.) (M.J.N.
and National
Incentive Grant
Science Foundation Grant No. DMR8514825
and P.M.C.).
We would like to acknowledge
the assistance
of the staff at the National Magnet Laboratory,
e s p e c i a l l y B.L.
Brandt,
c o n v e r s a t i o n s with
J.S.
Brooks,
M. Ya Azbel,
M.J.
and L.G. Rubin,
Burns,
and useful
P.K. Lam, and J.E. Northrup.
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