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Nonlinear optical properties of conjugated polymers
Synthetic Metals, 41-43 (1991) 3759-3762
3759
NONLINEAR OPTICAL PROPERTIES OF CONJUGATED POLYMERS
K.A.PRONIN and YU.I.DAKHNOVSKII Institute of Chemical Physics, Acad. Sci.USSR,
Moscow
(USSR)
ABSTRACT With
the
help
of
the
nonequilibrium
diagram
technique
we
rigorously calculate the nonlinear optical susceptibility for third harmonic
generation
carriers
is
taken
frequencies smeared
in
a
into
account.
corresponding
out
by
Peierls
dielectric. The
square
to one-third
damping.
Theoretical
Slow root
relaxation
of
divergencies
at
and the total results
are
in
band gap are qualitative
agreement with experiments on polyacetylene.
INTRODUCTION Conjugated polymers are promising materials for nonlinear optics (NLO) because of their high hyperpolarizabilities analytical been
expression
rigorously
for
found
the
third
without
order
taking
correlations and relaxation processes. soliton
contribution
to ts~
have
account
generation the
slow
in
a
been
of
(3)
Coulomb
presented
account in
[5].
for the process
one-dimensional
relaxation
susceptibility into
has
Computer calculations of the
paper we calculate the NLO susceptibility harmonic
[1-3]. In [4] the
carriers
dielectric that
In
this
of third
taking
into
originates
from
electron scattering on thermal phonons and impurities
[6].
RESULTS We use the continuum model of a Peierls dielectric Lin-Liu-Maki
type
contains
solitons.
no
0379-6779~1/$3.50
[7].
The polymer
ground
The
gap
complex
state
A=A s +A e i~ p
of Takayama-
is dimerised in
the
and
general
© Else~erSequoia~rintedin The Netherlands
3760 case
consists
dielectrics structure
two
for
the
of the
component
A
molecule)
P
dimerization
diagram
technique
=
and the function
is left. obtain
With the
generation
for
the
expression
the
trans-(CH)x
interaction
f is defined
only
with
from
the
resonance
weak damping
[4]. Drastic
square
root
because
of the
nonequilibrium
of
susceptibility factors
e :
divergences
by (2)
c3) = B 3 s
For brevity
inequality
are
now
smoothed
~ [~(l+i)
the resonance
divergence the
to ~-I/2>>i.
frequency
real
given real Note
in the resonance
damping,
can
but
is still
into part
the of
and
the
area
term
imaginary
z<~ where
b ] +...}
= 1/2
values
.
asymptotics
that damping
inversely
6~(I-i)
_5/2.1
the
by the first
values
of
the
latter
312
for
parts
produces for c=0
formula
+ ...} the
exhibits
in Eq.(4).
(3)
constants:
~/3 ~< ~1 _ z ~< 6-3~2a -2 the
- a -
63/2(~_Z)1/2
smoothly The
by
structure
finite
+
we give only the approximate
Below for ~(3)
damping.
takes
a -(z-o ) 8 =312
{
out
~e<
~(l-i)
Z--8
==he/IA l we
in the main term the result i arise in the vicinity of z=l,~. Here the
{ 12= I/2
, b = 81.63.
transforms
Ii-nzl>>=,
(Fig.l).
a = 2.41
= B
I/2] -2!in2}
frequences
For Iz-~l<<= the susceptibility proportional to small =i/2: XTHG
(i)
in f(z) and obtain
changes
highly pronounced
the
of the the
s
frequency,B=3-22-Te4 (~vf) lA l-~
= z-l(l-z2)-I/2{in[(l-z)*/2-i(l+z)
neglect
A
rigid
3
g(z)
of both
while
with
valid for small damping
= g(z-ic~IAl -I) - g(-z)
(3)
Peierls
state the component
electron
the help
f(z)
~THG
the
account
Here z--~/2 IA I is the dimensionless
of Wu
ground
of
into
'combined'
z -8 {3(l-8z2)f(3z)-8(l-4z2)f(2z)+(5-8z2)f(z)}
B
Far
For
is nonzero,
takes
we
for third harmonic (3)
interaction
that
Peierls
~THG
contributions.
that have a nondegenerate
(accounting the
of
Now
case a
of
zero
square
root
the peak
of X ~3~ are
a nonzero
(4)
values
proportional
tail
for
it was vanishing.
Im (3~
It means
that the nonlinear resonant behaviour is accompanied by absorption. Above the resonance z-!>>u, X (3) also matches the ==0 result: 3
3761 (3) = B z -8
~THG
Again that
the
even
peak
value
without
but reaches
- a -
65/2(Z--~) 3/2
{
of
Im
relaxation
a constant
63/2(Z--~)1 1/2 }
(3)
Re
is
proportional
X (3) for
z ~ !+0 3
, q ~ -83.18
For e=0 t h e p e a k
d(z)
= -2(2z-i) [ i + i ~ 2 - 3 / 2 ( 2 z - i ) - I / 2 ) ,
(l_2z) I/2,
! = 8~2(y-iA)
d(z)
does
not
Eq.(8)
The in
(6)
0 ~ 2! _ z ~ 1
(7a)
0 ~ z - i ~ 1 2
(7b)
damping { [ l + y 2 1 1 / 2 - y } l / 2 - i { [ l + y 2 1 1 / a + y } I/2
2z-i , y=
slightly
~i,
shifts
curves
of t h e The
while
its
within
in
and the
mechanism latter
of
show
dependence
of
parts
square to
is small
and
model
numerical gap
root
identical
do
Analysis with
of weak
for
damping.
for
e=0
Fig.l(b)
the
the
the
of
final
the
of with
lying Peierls
result
so
the
systems with a linearized
intensity
damping
both
difference
specifics
enter
coefficient
dependence
polymers
states, The
not
o n l y the
frequency
to all id d i e l e c t r i c
in s y s t e m s
divergences
nonzero
the
ground
prefactor.
formation
spectrum.
refraction
is
of X(3)are p r e s e n t e d
IX(3)1.
Consequently
nondegenerate
is a p p l i c a b l e
electron
imaginary
correspond
modulus.
this
degenerate only
Its m a g n i t u d e
w e n o t e t h a t the b a n d g a p A e n t e r s
through
X (3)
z=~ peak.
and
lines
curves
shows the frequency
B
real
fine
bold
Finally
the
(8)
2~
to i / 2
Fig.l(a).
[4],
diverge
in X(3):
[l+y2] I/2
proportional
Note
- i 19.11
= -4 2 I/2 ~
for n o n z e r o
-i/2
is d e f i n e d by
d(z)
while
to
n e g a t i v e v a l u e - B 38a.
T h e z =! ' r e s o n a n c e ' p r o d u c e s no d i v e r g e n c e 2 (3) 28 XTH c = B { p + q (2Z-I) + d(z) } p ~ 8.98 + i 2.81
(5)
will
dependent be g i v e n
index
of
in a f u t u r e
publication. After discrete Our
are
present
work
was
Su-Schrieffer-Heeger
curves
there and
the
agree some
with
First,
presented
in the
interval
z =~ r e s o n a n c e s the c u r v e of R e f . 8 2 the z e r o d a m p i n g result, w h i l e the
latter
and
is
learned
those
lower with
we
m o d e l was c a l c u l a t e d
qualitatively
differences.
completed
closer
to
for ours the
that
XTH c(3) in
recently in
[8],
between
IX(3)i g o e s
in
a
[8].
though i the z=~
considerably
practically experimental
coincides data
for
3762 (3) ~ T HG
(3) ZTH G I
v-
.j
I
i
I
3
2
I
Fig. l. The nonlinear susceptibility:
a) the real
(solid line)
imaginary
~ G(3) ("Z");
the
(dashed
line)
parts
of
b)
modulus
and of
(3) "z) XTHG(
•
polyacetylene
[3]. And second:
here Im~¢3)takes positive
the interval 0.35szs0.52 as in the c=0 regime,
while
values
in
in [8] it is
small and negative. REFERENCES 1
P.A.Chollet Nonlinear
et
al,
in
P.N.Prasad
Ovtic~
and
~lectroactive
and
D.R.Ulrich
Polymers,
(eds.),
Plenum,
N.Y.,
1988, p.121. 2
M.Sinclair, D.McBranch, (1989) D645.
3
W.S.Fann,
4
F.Kajzar, Phys.Rev.Lett.,62 (1989) 1492. W.Wu, Phvs.Rev.Lett.,61 (1988) 1119.
5
D.M.Mackie, R.J.Cohen and A.J.Glick, Phys.Rev. B,39 (1989) 3442.
6
Yu.I.Dakhnovskii
S.Benson,
and
D.Moses and A.J.Heeger,
J.M.J.Madey,
K.A.Pronin,
S.Etemad,
Svnth.Met.,~8
G.L.Baker
ProG.Symp. on Correlation
Effects in Low Dimensional Conductors and Superconductors, Kiev,May 1990, Springer, Berlin, in press. 7 8
and
H.Takayama, Y.R.Lin-Liu, K.Maki, Phvs.Rev.B,21 C.Wu and X.Sun, Phvs.Rev.B,41 (1990) 12845.
(1980) 2388.
3759
NONLINEAR OPTICAL PROPERTIES OF CONJUGATED POLYMERS
K.A.PRONIN and YU.I.DAKHNOVSKII Institute of Chemical Physics, Acad. Sci.USSR,
Moscow
(USSR)
ABSTRACT With
the
help
of
the
nonequilibrium
diagram
technique
we
rigorously calculate the nonlinear optical susceptibility for third harmonic
generation
carriers
is
taken
frequencies smeared
in
a
into
account.
corresponding
out
by
Peierls
dielectric. The
square
to one-third
damping.
Theoretical
Slow root
relaxation
of
divergencies
at
and the total results
are
in
band gap are qualitative
agreement with experiments on polyacetylene.
INTRODUCTION Conjugated polymers are promising materials for nonlinear optics (NLO) because of their high hyperpolarizabilities analytical been
expression
rigorously
for
found
the
third
without
order
taking
correlations and relaxation processes. soliton
contribution
to ts~
have
account
generation the
slow
in
a
been
of
(3)
Coulomb
presented
account in
[5].
for the process
one-dimensional
relaxation
susceptibility into
has
Computer calculations of the
paper we calculate the NLO susceptibility harmonic
[1-3]. In [4] the
carriers
dielectric that
In
this
of third
taking
into
originates
from
electron scattering on thermal phonons and impurities
[6].
RESULTS We use the continuum model of a Peierls dielectric Lin-Liu-Maki
type
contains
solitons.
no
0379-6779~1/$3.50
[7].
The polymer
ground
The
gap
complex
state
A=A s +A e i~ p
of Takayama-
is dimerised in
the
and
general
© Else~erSequoia~rintedin The Netherlands
3760 case
consists
dielectrics structure
two
for
the
of the
component
A
molecule)
P
dimerization
diagram
technique
=
and the function
is left. obtain
With the
generation
for
the
expression
the
trans-(CH)x
interaction
f is defined
only
with
from
the
resonance
weak damping
[4]. Drastic
square
root
because
of the
nonequilibrium
of
susceptibility factors
e :
divergences
by (2)
c3) = B 3 s
For brevity
inequality
are
now
smoothed
~ [~(l+i)
the resonance
divergence the
to ~-I/2>>i.
frequency
real
given real Note
in the resonance
damping,
can
but
is still
into part
the of
and
the
area
term
imaginary
z<~ where
b ] +...}
= 1/2
values
.
asymptotics
that damping
inversely
6~(I-i)
_5/2.1
the
by the first
values
of
the
latter
312
for
parts
produces for c=0
formula
+ ...} the
exhibits
in Eq.(4).
(3)
constants:
~/3 ~< ~1 _ z ~< 6-3~2a -2 the
- a -
63/2(~_Z)1/2
smoothly The
by
structure
finite
+
we give only the approximate
Below for ~(3)
damping.
takes
a -(z-o ) 8 =312
{
out
~e<
~(l-i)
Z--8
==he/IA l we
in the main term the result i arise in the vicinity of z=l,~. Here the
{ 12= I/2
, b = 81.63.
transforms
Ii-nzl>>=,
(Fig.l).
a = 2.41
= B
I/2] -2!in2}
frequences
For Iz-~l<<= the susceptibility proportional to small =i/2: XTHG
(i)
in f(z) and obtain
changes
highly pronounced
the
of the the
s
frequency,B=3-22-Te4 (~vf) lA l-~
= z-l(l-z2)-I/2{in[(l-z)*/2-i(l+z)
neglect
A
rigid
3
g(z)
of both
while
with
valid for small damping
= g(z-ic~IAl -I) - g(-z)
(3)
Peierls
state the component
electron
the help
f(z)
~THG
the
account
Here z--~/2 IA I is the dimensionless
of Wu
ground
of
into
'combined'
z -8 {3(l-8z2)f(3z)-8(l-4z2)f(2z)+(5-8z2)f(z)}
B
Far
For
is nonzero,
takes
we
for third harmonic (3)
interaction
that
Peierls
~THG
contributions.
that have a nondegenerate
(accounting the
of
Now
case a
of
zero
square
root
the peak
of X ~3~ are
a nonzero
(4)
values
proportional
tail
for
it was vanishing.
Im (3~
It means
that the nonlinear resonant behaviour is accompanied by absorption. Above the resonance z-!>>u, X (3) also matches the ==0 result: 3
3761 (3) = B z -8
~THG
Again that
the
even
peak
value
without
but reaches
- a -
65/2(Z--~) 3/2
{
of
Im
relaxation
a constant
63/2(Z--~)1 1/2 }
(3)
Re
is
proportional
X (3) for
z ~ !+0 3
, q ~ -83.18
For e=0 t h e p e a k
d(z)
= -2(2z-i) [ i + i ~ 2 - 3 / 2 ( 2 z - i ) - I / 2 ) ,
(l_2z) I/2,
! = 8~2(y-iA)
d(z)
does
not
Eq.(8)
The in
(6)
0 ~ 2! _ z ~ 1
(7a)
0 ~ z - i ~ 1 2
(7b)
damping { [ l + y 2 1 1 / 2 - y } l / 2 - i { [ l + y 2 1 1 / a + y } I/2
2z-i , y=
slightly
~i,
shifts
curves
of t h e The
while
its
within
in
and the
mechanism latter
of
show
dependence
of
parts
square to
is small
and
model
numerical gap
root
identical
do
Analysis with
of weak
for
damping.
for
e=0
Fig.l(b)
the
the
the
of
final
the
of with
lying Peierls
result
so
the
systems with a linearized
intensity
damping
both
difference
specifics
enter
coefficient
dependence
polymers
states, The
not
o n l y the
frequency
to all id d i e l e c t r i c
in s y s t e m s
divergences
nonzero
the
ground
prefactor.
formation
spectrum.
refraction
is
of X(3)are p r e s e n t e d
IX(3)1.
Consequently
nondegenerate
is a p p l i c a b l e
electron
imaginary
correspond
modulus.
this
degenerate only
Its m a g n i t u d e
w e n o t e t h a t the b a n d g a p A e n t e r s
through
X (3)
z=~ peak.
and
lines
curves
shows the frequency
B
real
fine
bold
Finally
the
(8)
2~
to i / 2
Fig.l(a).
[4],
diverge
in X(3):
[l+y2] I/2
proportional
Note
- i 19.11
= -4 2 I/2 ~
for n o n z e r o
-i/2
is d e f i n e d by
d(z)
while
to
n e g a t i v e v a l u e - B 38a.
T h e z =! ' r e s o n a n c e ' p r o d u c e s no d i v e r g e n c e 2 (3) 28 XTH c = B { p + q (2Z-I) + d(z) } p ~ 8.98 + i 2.81
(5)
will
dependent be g i v e n
index
of
in a f u t u r e
publication. After discrete Our
are
present
work
was
Su-Schrieffer-Heeger
curves
there and
the
agree some
with
First,
presented
in the
interval
z =~ r e s o n a n c e s the c u r v e of R e f . 8 2 the z e r o d a m p i n g result, w h i l e the
latter
and
is
learned
those
lower with
we
m o d e l was c a l c u l a t e d
qualitatively
differences.
completed
closer
to
for ours the
that
XTH c(3) in
recently in
[8],
between
IX(3)i g o e s
in
a
[8].
though i the z=~
considerably
practically experimental
coincides data
for
3762 (3) ~ T HG
(3) ZTH G I
v-
.j
I
i
I
3
2
I
Fig. l. The nonlinear susceptibility:
a) the real
(solid line)
imaginary
~ G(3) ("Z");
the
(dashed
line)
parts
of
b)
modulus
and of
(3) "z) XTHG(
•
polyacetylene
[3]. And second:
here Im~¢3)takes positive
the interval 0.35szs0.52 as in the c=0 regime,
while
values
in
in [8] it is
small and negative. REFERENCES 1
P.A.Chollet Nonlinear
et
al,
in
P.N.Prasad
Ovtic~
and
~lectroactive
and
D.R.Ulrich
Polymers,
(eds.),
Plenum,
N.Y.,
1988, p.121. 2
M.Sinclair, D.McBranch, (1989) D645.
3
W.S.Fann,
4
F.Kajzar, Phys.Rev.Lett.,62 (1989) 1492. W.Wu, Phvs.Rev.Lett.,61 (1988) 1119.
5
D.M.Mackie, R.J.Cohen and A.J.Glick, Phys.Rev. B,39 (1989) 3442.
6
Yu.I.Dakhnovskii
S.Benson,
and
D.Moses and A.J.Heeger,
J.M.J.Madey,
K.A.Pronin,
S.Etemad,
Svnth.Met.,~8
G.L.Baker
ProG.Symp. on Correlation
Effects in Low Dimensional Conductors and Superconductors, Kiev,May 1990, Springer, Berlin, in press. 7 8
and
H.Takayama, Y.R.Lin-Liu, K.Maki, Phvs.Rev.B,21 C.Wu and X.Sun, Phvs.Rev.B,41 (1990) 12845.
(1980) 2388.