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Hysteresis of microwave magnetotransmission in Y-Ba-Cu-O films
Physica B 169 (1991) North-Holland
HYSTERESIS
OF MICROWAVE
A.M.GRISHIN, Donetsk
627-628
Yu.M.NICOLAENKO,
Physico-Technical
A new technique Irreversible
Demagnetization
fields
normal
phase
1.
Two
series
of films
target
strata tering
(1012). Series of the ceramic
buffer
sublayer
In figure resistivity
of properties
of separated
grains
concentration
stipulate
Y-Ba-Cu
Series
I was
of the multicom-
onto the sapphire
sub-
II was prepared by the ion sputtarget onto the sapphire with the
ZrOz.
1 the temperature
R,(T)
dependences
and th e transmission
of the dc
coefficient
t(T)
are given. t(T) equals to the ratio of the transmission power to the incident one. The R(T) curve of the film I shows the abrupt a smooth
change
at T, = 80K.
shape up to 30K.
film II shows
Curve
The resistance
a semiconducting
of Sciences,
FILMS
high-ir,
t(T)
has
curve of the
temperature
to 80K. Then at T, = 80K it gradually reaches the 820 value at 4.2K.
trend
declines
up and
340114
for hysteresis. transport
Donetsk,
superconducting
field has experimental The
1.1 d 10’s crnd3 and mobility
were studied, sputtering
Academy
of granulated
upon magnetic
even in cases of the films not showing
by the magnetron
posed metallic
of the Ukrainian
of resistivity
field of the grain,
IN Y-Ba-Cu-0
E.N.UKRAINTSEV
Institute
of invesigation
dependence
critical
prepared
MAGNETOTRANSMISSION
2
USSR
films has been
studied
and explained
superconducting
phase
developed.
theoretically. concentration,
. 10s cm’jl;
set of effective carriers in the current have been determined.
superconducting
The curves
tH vs the magnetic
ure 2. A hysteresis
field are given in fig
of the film magnetization
occurs
at
the temperature below T,. The transmission minimum is at H = 0, if the film is cooled in the zero magnetic field.
With
increases
the field growth
minimal
increase
(see insert
to fig.2).
with
2. The presented by a simple model. normal
conducting
grains.
We assume grains
trodynamics ity tensor
the magnetizing
matrix that
containing
are absent.
equation.
We describe
if the wavelength which
coefficient to
2
I
+ (2rda,,/c)2
in vacuum
in its turn
c/w exceeds
exceeds
conductiv-
is found from
2rdo,,/c
(1 + 2ndo.,/c)2
contacts
the films elec-
of the effective
It is equal 1+
=
superconducting
the superconducting
by introduction
the Maxwell
field growth
experimental data can be described It is as follows; HTSC-film is a
6. The transmission
t
reversal
The sign of Hmi,
to the direction of the magnetizing field. of H,,,;, and of the transmission coefficient
minimum
between
coefficient
At magnetization
tH shifts to the field Hmi,.
corresponds The values
depth,
the transmission
to the saturation.
(1)
the skin layer
the film thickness
d:
d << c/(27rwcr)f << c/w. The axes x and y are in the film plane. The film dc resistance is Ro = (cd)-‘. It means 0
ioo
200
T,K
0
that
in the
absence
c7“u = 0 we have a simple 0
(00
200
of magnetic
relation
field when
for Ro and t:
T,K
Ro = + The temperature
FIGURE dependences
and the microwave films I, II of thickness curve is the R,(T)
4t
1 of the resistivity
transmission
coefficient
0.8 and 3 pm. calculated
and experimental
R.
t for t,he
The continuous
with the help of eq.2 values t(T).
As it is seen from figure 1, Es.(Z) is valid within the experimental accuracy. Influence of the magnetic field I? on micr_owave transmission is due to the dependence of 6 on H. tH variations not exceed the value 1 + 2 dR. It means that a
628
AM.
Grishin
et al. I Microwave
in Y-Ba-Cu-0
magnetotransmission
form magnetic
films
field
i;(,-) = ti + $X,R;
7
v
10%
k-: ITI at the surrounding
8
normal
ni, is the magnetization the external
7
magnetic
field.
fields are the long-range is composed
6
phase.
Qr’)
at r;, H is
The grain demagnetization
ones.
of the average <
Here Ri is the radius,
of the grain positioned Therefore
the field i;(T)
value,
>=
E7 - p47rti
(5)
I&
5
and the fluctuations
with the amplitude
?.3
J<
B .s
to% !.2
I
P
I
-
1
t.90 t
/’
c
o.5
Yn)
fi
p is a relative
volume
2.1 - Z.1
grains. If one proceeds
2 -
4am = -H(l-n)-‘,
10
_ 9
to pushing
I
I
,
,
4
6
8
,
,
,
FIGURE
of the transmission
coefficient t(H). The dependences of the minimal value of transmission coefficient t,,, and its position H,,+, on the magnetizing
field value are given.
small group of carriers is responsible us assume carriers
that
there
p is carriers eq.(l)
+ ?),
mobility,
of the great above effect.
are a basic
with conductivity
c7“%I- %r/(l Then
possessing
for the considered
group
of low-mobile
magnetic
1 + y2(tol~~)“2
2
field.
will be,
tff = to
describes
experimental
curves
E.g., for the film I at T = 4.2K 00s = 3.5 x 10’ (!&XL-‘, concentration
mobility
1.1 x 10’6cm-3
of mobile carriers. 3. The system of spherical
shown in figure 2.
we obtain
the grains.
H,(l
In the strong
- n) the flux penetrates there
(H,
= H,/&). state,
in the grains 4?rm;,.
fields are directed
opposite
If
the resid-
is directed
field I?. In the intergrain
along
space the deto z and they
(5) and (6) it follows that is achieved at the field H,,,i,
H,;,
and corresponded zation
= 4apm1
~1 = 2.5 x 103,
n = 2 * lo5 cm*/Vsec,
and mean free path 0.8 pm grains induces the nonuni-
- 4nX(p + 2/g) 1 - 4xxp
to the minimum
of <
It allows one to reconstruct curve m(H).
hi
(7) > value, x =
the grain magneti-
It should be taken into account
at field removal the residual according
the de-
by relationship:
magnetization
to the law 4s 1 mres /= (l/n)[H
and x = -1/4xn.
(3) [ 1 + y2(toltcn) I Here to = [1+ 2nd(u, + aoz)/c]-2, t, = [l + 2ad~i/c]-~. Eq.(3)
termined
dm/dH.
= Phlc
h is the internal
fac-
let
ui and the group with o+I = floz/(l + -?),Y
then
From the formulae transmission minimum
mobility Really,
state,
compensate the external field. It means that the average inner field (5) becomes zero at H j. 0 at field removal.
2
field dependences
the demagnetized
and is pinned
the magnetizing magnetization
The magnetic
superconducting
now from the magnetized
ual magnetization
10 H,KOe
with
(6)
where n is the demagnetization
the flux outside
one proceeds
2
occupied
from
field exceeding
into the grains
-4 -2
= (4?Tm/3)&
tor. It means that the average inner field in the medium becomes by 1 + ~(1 - n)-i times greater than H due
magnetic
-6
> - < L>2
Comparison
becomes -
that zero
H, . (1 - n)]
of relationship
(7) with
the experimental dependence H,,,,,(H) shown in figure 2 gives for the film I with n = 0.81 the values p = 0.12 and H., = 12.1 kOe.
HYSTERESIS
OF MICROWAVE
A.M.GRISHIN, Donetsk
627-628
Yu.M.NICOLAENKO,
Physico-Technical
A new technique Irreversible
Demagnetization
fields
normal
phase
1.
Two
series
of films
target
strata tering
(1012). Series of the ceramic
buffer
sublayer
In figure resistivity
of properties
of separated
grains
concentration
stipulate
Y-Ba-Cu
Series
I was
of the multicom-
onto the sapphire
sub-
II was prepared by the ion sputtarget onto the sapphire with the
ZrOz.
1 the temperature
R,(T)
dependences
and th e transmission
of the dc
coefficient
t(T)
are given. t(T) equals to the ratio of the transmission power to the incident one. The R(T) curve of the film I shows the abrupt a smooth
change
at T, = 80K.
shape up to 30K.
film II shows
Curve
The resistance
a semiconducting
of Sciences,
FILMS
high-ir,
t(T)
has
curve of the
temperature
to 80K. Then at T, = 80K it gradually reaches the 820 value at 4.2K.
trend
declines
up and
340114
for hysteresis. transport
Donetsk,
superconducting
field has experimental The
1.1 d 10’s crnd3 and mobility
were studied, sputtering
Academy
of granulated
upon magnetic
even in cases of the films not showing
by the magnetron
posed metallic
of the Ukrainian
of resistivity
field of the grain,
IN Y-Ba-Cu-0
E.N.UKRAINTSEV
Institute
of invesigation
dependence
critical
prepared
MAGNETOTRANSMISSION
2
USSR
films has been
studied
and explained
superconducting
phase
developed.
theoretically. concentration,
. 10s cm’jl;
set of effective carriers in the current have been determined.
superconducting
The curves
tH vs the magnetic
ure 2. A hysteresis
field are given in fig
of the film magnetization
occurs
at
the temperature below T,. The transmission minimum is at H = 0, if the film is cooled in the zero magnetic field.
With
increases
the field growth
minimal
increase
(see insert
to fig.2).
with
2. The presented by a simple model. normal
conducting
grains.
We assume grains
trodynamics ity tensor
the magnetizing
matrix that
containing
are absent.
equation.
We describe
if the wavelength which
coefficient to
2
I
+ (2rda,,/c)2
in vacuum
in its turn
c/w exceeds
exceeds
conductiv-
is found from
2rdo,,/c
(1 + 2ndo.,/c)2
contacts
the films elec-
of the effective
It is equal 1+
=
superconducting
the superconducting
by introduction
the Maxwell
field growth
experimental data can be described It is as follows; HTSC-film is a
6. The transmission
t
reversal
The sign of Hmi,
to the direction of the magnetizing field. of H,,,;, and of the transmission coefficient
minimum
between
coefficient
At magnetization
tH shifts to the field Hmi,.
corresponds The values
depth,
the transmission
to the saturation.
(1)
the skin layer
the film thickness
d:
d << c/(27rwcr)f << c/w. The axes x and y are in the film plane. The film dc resistance is Ro = (cd)-‘. It means 0
ioo
200
T,K
0
that
in the
absence
c7“u = 0 we have a simple 0
(00
200
of magnetic
relation
field when
for Ro and t:
T,K
Ro = + The temperature
FIGURE dependences
and the microwave films I, II of thickness curve is the R,(T)
4t
1 of the resistivity
transmission
coefficient
0.8 and 3 pm. calculated
and experimental
R.
t for t,he
The continuous
with the help of eq.2 values t(T).
As it is seen from figure 1, Es.(Z) is valid within the experimental accuracy. Influence of the magnetic field I? on micr_owave transmission is due to the dependence of 6 on H. tH variations not exceed the value 1 + 2 dR. It means that a
628
AM.
Grishin
et al. I Microwave
in Y-Ba-Cu-0
magnetotransmission
form magnetic
films
field
i;(,-) = ti + $X,R;
7
v
10%
k-: ITI at the surrounding
8
normal
ni, is the magnetization the external
7
magnetic
field.
fields are the long-range is composed
6
phase.
Qr’)
at r;, H is
The grain demagnetization
ones.
of the average <
Here Ri is the radius,
of the grain positioned Therefore
the field i;(T)
value,
>=
E7 - p47rti
(5)
I&
5
and the fluctuations
with the amplitude
?.3
J<
B .s
to% !.2
I
P
I
-
1
t.90 t
/’
c
o.5
Yn)
fi
p is a relative
volume
2.1 - Z.1
grains. If one proceeds
2 -
4am = -H(l-n)-‘,
10
_ 9
to pushing
I
I
,
,
4
6
8
,
,
,
FIGURE
of the transmission
coefficient t(H). The dependences of the minimal value of transmission coefficient t,,, and its position H,,+, on the magnetizing
field value are given.
small group of carriers is responsible us assume carriers
that
there
p is carriers eq.(l)
+ ?),
mobility,
of the great above effect.
are a basic
with conductivity
c7“%I- %r/(l Then
possessing
for the considered
group
of low-mobile
magnetic
1 + y2(tol~~)“2
2
field.
will be,
tff = to
describes
experimental
curves
E.g., for the film I at T = 4.2K 00s = 3.5 x 10’ (!&XL-‘, concentration
mobility
1.1 x 10’6cm-3
of mobile carriers. 3. The system of spherical
shown in figure 2.
we obtain
the grains.
H,(l
In the strong
- n) the flux penetrates there
(H,
= H,/&). state,
in the grains 4?rm;,.
fields are directed
opposite
If
the resid-
is directed
field I?. In the intergrain
along
space the deto z and they
(5) and (6) it follows that is achieved at the field H,,,i,
H,;,
and corresponded zation
= 4apm1
~1 = 2.5 x 103,
n = 2 * lo5 cm*/Vsec,
and mean free path 0.8 pm grains induces the nonuni-
- 4nX(p + 2/g) 1 - 4xxp
to the minimum
of <
It allows one to reconstruct curve m(H).
hi
(7) > value, x =
the grain magneti-
It should be taken into account
at field removal the residual according
the de-
by relationship:
magnetization
to the law 4s 1 mres /= (l/n)[H
and x = -1/4xn.
(3) [ 1 + y2(toltcn) I Here to = [1+ 2nd(u, + aoz)/c]-2, t, = [l + 2ad~i/c]-~. Eq.(3)
termined
dm/dH.
= Phlc
h is the internal
fac-
let
ui and the group with o+I = floz/(l + -?),Y
then
From the formulae transmission minimum
mobility Really,
state,
compensate the external field. It means that the average inner field (5) becomes zero at H j. 0 at field removal.
2
field dependences
the demagnetized
and is pinned
the magnetizing magnetization
The magnetic
superconducting
now from the magnetized
ual magnetization
10 H,KOe
with
(6)
where n is the demagnetization
the flux outside
one proceeds
2
occupied
from
field exceeding
into the grains
-4 -2
= (4?Tm/3)&
tor. It means that the average inner field in the medium becomes by 1 + ~(1 - n)-i times greater than H due
magnetic
-6
> - < L>2
Comparison
becomes -
that zero
H, . (1 - n)]
of relationship
(7) with
the experimental dependence H,,,,,(H) shown in figure 2 gives for the film I with n = 0.81 the values p = 0.12 and H., = 12.1 kOe.