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Hyperfine interaction and crystalline environment in NdTi(Fe1−xCox)11 compounds by 57Fe Mössbauer study
Physica B 179 (1992) North-Holland
PHYSICA L?
89-93
Hyperfine interaction and crystalline environment NdTi( Fe 1_$o,) 1 1 compounds by 57Fe Mijssbauer Jifan
Hu,
Ziwen
Dong,
Yinglie
Liu
and
Zhenxi
in study
Wang
Institute of Ph,ysics, Academia Sinica, Beijing 100080, China Received 3 December 1990 Final received I7 January 1992
In this paper, the Mossbauer spectra for NdTi(Fe I XCo,),, compounds have been investigated. The hyperfine interaction has been studied with respect to the crystalline environment. The results show that cobalt atom prefers to occupy the 8f site in the range of high iron content and iron atom prefers to occupy the 8j site in the range of high cobalt content. The variations of the magnetic moments for each iron site 8i, 8j and 8f are very small with increasing cobalt content in compounds. At the step of the initial replacement of the iron atom by cobalt, the quadrupole splittings QS and isomer shift IS for the 8f site increase and for 8i decrease corresponding to the occupation preference on the iron site for cobalt atoms. Similar composition dependences of QS and IS implies that there exists a shielding effect or coupling of s-d electrons in the compounds
1. Introduction The Fe-rich compounds of the type ,zPvMg (R = rare earth, M = Ti, Cr, V, MO, RFe W) are. of the body-centered tetragonal ThMn,, structure. The large solid solution range is achieved with M =V (1.4~~ < 3.5), but quite narrow for Ti (O.S
0
1992 - Elsevier
Science
fur Metall1, W-7000
Publishers
occupation of 16k2 [9], which has a relatively small interatomic distance between 3d atoms. Such a small interatomic distance is likely to favour an antiferromagnetic interaction. The preferential site occupation on 16k, of cobalt is attributed to the relatively strong initial increase of the Curie temperature with the replacement of iron by cobalt. The most interesting case is the 57Fe Mossbauer effect on Nd,(Fe, _,Co,),,B in the range of high cobalt content for which Van Noort and Buschow [lo] and Honma et al. [9] found strong evidence for a strong preference of the Fe atoms for the 8j, site, which has a relatively large number of 3d nearest neighbours. These results are in good agreement with a neutron diffraction study of Nd,(Fe, ,Co,) ,4B by Herbst and Yelon [ll]. As we know, we can understand something about the influence of the crystalline environment on the hyperfine interaction in the compounds via the hyperfine field, isomer shift and quadrupole splitting, and to compare them with the results of magnetic measurements, neutron diffractions and band structure calculations. To obtain the relationship between the local mag-
B.V. All rights
reserved
Experiment
2.
‘l‘hc NdTi( noniinnl pdrcd 00.5
Fc,
b>
with
,C‘oi ), , compounds
composition
the
~\-= 0.09LO.S26
LVCI-c prc-
the
of
melting
clcnients
purlt!
M’t’; or bcttcr under argon atmosphcrc.
button
ingots
wcrc
melted
then
scalecl
homogeneity.
annealed tion
of
in
timcs
ThMn
;I the
bc essentially
,? tetragonal
second
phase
The
Miissbaucr-
po~~nds.
using
to
;I constant
temperature. using
of The
cr-Fe
a11
sp&tr:r
“(‘0
The
amount
in
the
wcrc
scale
with dt
;I
room
calibrated
W;I~
at room
con-
mcasurcci
palladium
velocity
absorber
the phase
spectrometer
in
and
diffrac-
;i single
small
accclcration
50 niC~‘i source
tube
indicated
of
vcrv
CI~SLII-c
X-ray
structure.
is
The
to
quartz
;I
at 900°C for two weeks. ( Co-Ka radiation) patterns
compounds with
four
tcmperaturc.
1;lllcc
3.
hcthccI1
pcrfinc ‘I‘hc with
Miissbauer
spectra
.\-= O.(W.
mcasurcci
0.775.
room
at
of
NdTi(
0.454.
Fc,
O.h32
temperature
/ <‘oi ) , ,
and
O.S2h
arc shown
in fig.
kc
ne
timely.
Results and discussion
ticid
Si
1.c
ha\c
the
the
\itc
4incc
ncarcst
ncighbour
Iarget
avci-age
smallest
e;Ich
dlou1d
;ltolll\
site
IOI
Si
nunibcl-
ot iron
ticlci should
corrq~ond
\ifC hince it ha4 the dlortcst
atomic
clistancc.
distribution
iron
hypcrfinc
broader
line
the site
environment.
shape comes
do111
distribution
has
an influence
neighhour knowlccigc
that ha5
ncighbour In this for NciTi( ments
or
Fe, were
ncighbour
the
atom
the
site.
hypedine
titanium
:I
, Co, ) , ,
of
compou~lds.
performed environment
or
the r;u-
in
shells
used
for
anal!,sis, such
and
xpectra
KFc
the
continuou\ a
assign-
table
the
nearest
ments
dis-
ing
the
had been
INII
the St
“Fc
a11d
With
Miissbaucl
successf’ully
cur\ c through
tit to the of
quadrupole
i-clati\e
both
caih
In
fitted
[ 121.
reprcscntk
tf,,,.
,,,\I,
tor
for the Si 5itc.
of’ assignment.
for
previously
~uby~ectrum
one
kind
a
t Iic
r:e- l-‘c Intel
in fitting.
arc for
the> 10
5ubspectra
to be introduced
~MO subhpcctra
\itt‘\
Xj
site
the interatomic
haI
parameters
[ 12. 1.31. was
Gtc
The
nearest
spectra The
the
decreaw~ the
method
the
which
next-nearest
ticki
considering and
;I
01
considering
atoms
least-squares
fitting
from
at the tii site
nenrcst
iron
Such
the multiplicit?
next-neighbour
work.
computer
on each
when
from
[4],
It originates
of Ti
for
iron
fields
II\-
largc>\t
atom5 2nd the
St’ iron
of
the
nieanwhilc
1. The outer lines of the spectra arc broadci- than t hc inner 011~5. indicating that there exists ;I
I ip to tucl
rc~pcc
Iargc41
has
fccaPte cli4t;incc.
hi pcrtinc
4ltC’.
intcnsit\
the
for
OS. cad1
I. Wc try to derive of the F;e \ublatticcs
hvpcrfinc
The
\ubspectra.
splitting I
the data point\
spectrum.
tietcia. ‘l‘hc
isomer iron
site
average from
hypcrlinc
hyperfine
licld
diift
IS
and
art‘ listed
niiignctic
ii) ilio-
the corrcspon&
approximation
xhoulrl
.I. Hu et al.
I ‘?Fe Miissbauer studies on NdTi(Fe,
be made for the hyperfine interaction constant, the proportional factor between the average iron moment of the alloy and the average hyperfine field. Here, we adopt a proportional factor of 15.6T/p., derived from ref. [13]. The composition dependence of the average hyperfine field and the average magnetic moment of iron atoms for NdTi(Fe,_.Co,), , system are shown in fig. 2. One can clearly see that with the replacement of the iron by cobalt, the average hyperfine field as well as the average iron magnetic moment increases at first. and then decreases. The peak point appears at about x = 0.27. It is interesting to point out that a maximum at about x = 0.27 for the saturation magnetization in RTi(Fe,_,Co,),, has also been found by Sinha et al. from magnetization measurements [a]. It implies that besides the effect of the relative small magnetic moment of the cobalt sublattice. the change of the magnetic moment of the iron sublattice also plays an important role in the total saturation magnetization M, of the RTi(Fe, _rC~x)l, system. A maximum when present at low temperature T = 4.2 K for Fe-Co based magnetic materials can be easily explained by the process of electron transfer between the 3d spin up and spin down energy band. However, at high temperature, such as room temperature, the effect of electron transfer
>Co,),,
0.00
0.20
compounds
0.40
X
91
0.60
x = 0.092
x = 0.275
x = 0.459
x = 0.642
x = 0.826
8i Xj Xf Xi 8j 8f 8i 8j 8f 8i *j 8f 8i 8j 8f
-0.024 -0.134 -0.124 -0.038 -0.131 -0.111 -0.004 -0.045 -0.086 -0.100 -0.022 -0.135 -0.050 -0.007 -0.094
for a similar maximum is not so clear due to the complicated temperature dependence of the 3d spin up and spin down energy band. When considering the composition dependence of the magnetic moment for each iron site 8i, Sj and 8f, shown in fig. 3, it seems that the variation of the magnetic moment is very small, which can be only called as some kind of fluctuation. In such case, it is not easy to understand why there is such a maximum. We can only say that the maximum may be originates from the counteracting effects of the increase of Curie temperature T, and the decrease of 3d sublattice magnetization with increasing the cobalt content. The composition dependence of the iron occu-
QS (mm/s)
-0.124 -0.175 -0.118 -0.024 -0.084 0.010 -0.064 -0.050 -0.031 -0.032
1.00
Fig. 2. The composition (x) dependence of the average hyperfine field (H,,) and the average iron atom magnetic moment (MFc) for the NdTi(Fe,_,c~~),, system.
Table 1 Isomer shift IS, quadrupole splitting QS, hyperfine field H,, and relative intensity I of each of the subspectra sites Si, Sj and 8f in the NdTi(Fe,_,Co,),, compounds with x = 0.092, 0.275, 0.642 and 0.826. IS (mm/s)
0.80
0.098 0.056 0.093 0.089 0.002 0.098 0.027 0.100 0.166 -0.154 0.016 0.078 0.058 -0.053 0.168
0.086 0.279 0.103 0.166 0.042 0.065 0.074 0.232
30.6 27.6 22.4 30.3 27.8 23.0 31.2 28.5 22.7 31.1 28.3 23.3 31.3 28.7 23.1
iron
I (%
H,,(T) 0.080 0.026
for the three
25.2 18.9 25.7 20.5 25.5 20.2 26.1 20.3 25.8 19.7
36 20 20 37 13 17 20 29 12 10 27 30 5 13 28
21 3 2x 5 34 5 26 7 49 5
‘I he
‘xullposItlon
depe11dc11ce
splitting
rup’)Ic
(C)S)
qC’(jt 1,
1hc
‘,I
col~~llt
MC’
~211
I-;ingc 0,.?75.
\
cx~ntrar\
. QS( SI )
1
only range
content
l’or
three
ircjn
i),(145. WC thinh. cxntial in fig.
4.
the
We
Sf Gte
f-c prcfcI-s the
each iron
A
result
interaction. the
the
(‘ohnit. ;I
1:ehavioIof
the St atoms the distance
a
larger of
relative
i4
ma>
the
increases. increases
rapidly
of iron
lw cobalt.
WC
antiferromagncti~,
Thercforc.
interaction
the with
the
Curie initial
tenrc‘-
on
of the
St
QS
clecrcascs.
With
tent.
Si
the
tion NdTi(
PC,
the
the
XI
atom
will
ix
1’
that
\alcncc
the
contribution
QS
t’)
>ysem
cjt‘ CjS Iv
incrcaes
sites
coI;p’ment
lcurthcrniorc. 01 clcctric
hb to
-incre;isc tountl conIp<>\~-
the niainl\~
/I1
field
the
clrtcI-Ininccl
of the- c.lcctric wc want
III
replaccIncIIt atoll1
term
CX)I~
cobalt.
The
cobalt
is
SI and Si
been
[“I.
with ;I
to the clcctric
cbcculxclu;~ci~-upolc
of the cxAxrlt
have
I
i\ I’) w\
(Kf).
bcgina
data )i ,B
4plittIn~
That the
the
and thc*lI
the prelcl-
occupied
, (‘0, ) i ! 4vsteni
principal
with
hits.
cohall
O.S1h. first
\ =z 0.002
cohalt.
‘111~1
In the
t hc preferential
QS( Si )
gradient
111c1-c;Iw
accord
i1.011 \Itc.
5itc
Fe / ,(‘o, iron
\
to \
the increasing
clep~ndencc the
I\1
from
ot
experimental
Nd,(
the
1177.q
tkm
t”)r the unoccupied
~oI-I-cspondin~l~. Similar
the
In
01 the cluaclrupolc
to
cotwIt
On
dccreaw
)
0 IFI
‘wulxrtion
Meanwhile.
t)l
ciecre~rscs and
fcrromagnctic
hchavior
site.
01
4plittIng
‘)t
excha~igc
the Xf iron
tion
the
amdlcr
magnetic
on the Xf site
the
intc‘r-
of an antiferromagneti~
pcrature placement
Xj)
to occupy
prcqx)rtion
Fe-Fc
In
4itc
c’~rresponciin~
t hal.
and
content.
t-‘c-Fe distance
with
and
prefers
pl-oportion
content
between
;I short
i\ shoun to occup>
iron
shortest
A.
occurrcncc
radius.
interaction
of high the
is 2.392
Such
interaction.
thinh
Co prefers
St‘) and Ftz( Xf)-Fe( 141.
in the
atomic
Sj and tif.
in the high cobalt
4ysteni.
distance
I;c( St’-Fc( 7.454
that
range
to Sj site
KFc,,I‘i
atomic
can SW
in the
Si.
site,
1’1
quadrupol~~
ttlc
4itc4 decrease\
pcrhap\
III
incrcax.\.
CjS(Si)
\ite\
III
5.
O.O’C
\
tlecre~iacs.
\
ir’)n
‘I‘hc trends
the
Si
:incf
QS( Si) trc)ni
CJS ot all three incI-c;isc\.
C_K(
c0nte11t
QS( Xi)
11.159.
only
Gtc
iu liy.
fr0111
that
quad
iron
I\ 4houn
OS(H).
:incl
~x,h;llt
the
incanwhilc
for
~c’c’
ol the St \itc.
ot
each
c011te11t
splitting
l~allgc
pation
\v\lcni
NdI’i(I-c!
the
ot
tor
to p’jirit gI\c\
grxlient
field ou1
(El-G I
J. Hu et ul. I ‘7Fe Mhshauer
studies on NdTi(Fe,
-01
Fig. 6. The composition (x) dependence of isomer for each iron site 8i. 8j and 8f in the NdTi(Fe, system.
shift IS rCo,),,
shift (IS) for each iron site in the system are shown in fig. 6. NdTi(Fe,_,Co,),, The isomer shift IS of the Mossbauer spectrum for “Fe is proportional to the local electronic charge density p(O) at the “Fe nuclear position and therefore is related to the spatial distribution of the electrons surrounding the nuclei. The electron distribution can change not only with a change in the number and character of electrons but also with a surrounding the 57Fe nuclei, change in the distribution of the nearest neighbours of the iron atom. The isomer shift is essentially determined by the number of s-electrons of the nearest-neighbor iron atom. From fig. 6, one can easily see that the isomer shift of 8f increases (the absolute value of the negative IS decreases) with the initial preferential occupation by cobalt atom on the 8f site, which is very similar to the results of calculations and experiments on the system of Co-impurity in Fe [14]. It may be implies that the number of s-like electrons at the 8f iron site decreases in this case. Meanwhile, from fig. 6 we can also see that the IS of 8i decreases and the IS of 8j increases slightly with the initial increase of the cobalt content in the compound. We do not know
I Co<),, compounds
93
exactly in this case how much the local d charge or the intra-atomic screening affect the IS. Comparing the composition dependence of quadrupole splitting QS and isomer shift IS in the range of small content of cobalt atoms in compounds, it is very interesting to find that two dependences are somewhat similar. It implies that there exists a shielding effect or a coupling of s-d electrons. However, since the relative accuracy of the values of the quadrupole splitting and the isomer shift are less than that of the hyperfine held and there exist four types of atoms (Nd, Ti, Fe and Co) in compounds, the complications of the shielding effect of s-d electrons increase. Speaking frankly, to give an exact analysis on the density of s or d electric charge at such case is almost impossible.
References
[II
D.B. de Mooij and K.H.J. Buschow, J. Less-Common Metals 136 (1988) 207. PI Jifan Hu, Tao Wang. Shougong Zhang, Yizhong Wang and Zhenxi Wang, J. Magn. Magn. Mater. 74 ( 1988) 22. PI R.B. Helmholdt, J.J.M. Vleggaar and K.H.J. Buschow. J. Less-Common Metals 138 (1988) Ll 1. [41 0. Moze, L. Pareti, M. Solzi and W.I.F. David. Solid State Commun. 66 (1988) 465. D.B. de Mooij and [51 F.R. de Boer. Huang Ying-Kai. K.H.J. Buschow, J. Less-Common Metals 135 (1987) 199. VI Jifan Hu, Yizhong Wang, Ruwen Zhao, Taishan Ning, Zhenxi Wang, Solid State Commun. 70 (1989) 983. [71 K.H.J. Buschow. J. Appl. Phys. 63 (1988) 3130. [81 V.K. Sinha. S.F. Cheng, W.E. Wallace and S.G. Sankar. J. Magn. Magn. Mater. 81 (1989) 227. PI H. Honma and H. Ino, IEEE Trans. Magn. MAC-23 (1987) 3116. [lOI H.M. Van Noort and K.H.J. Buschow. J. Less-Common Metals 113 (1985) L9. [Ill J.F. Herbst and W.B. Yelon. J. Appl. Phys. 60 (19X6) 4224. iI21 A. Deriu. G. Leo. 0. Moze, L. Pareti. M. Solzi and K.H. Xue, Hyperfine Interactions 45 (1989) 241. [13] Bo-Ping Hu. Hong-Shou Li and J.M.D. Coey, Hyperfine Interactions 45 (1989) 233. [ 141 P.H. Dederichs, R. Zeller, H. Akai and H. Ebert. J. Magn. Magn. Mater. 100 (1991) 241.
PHYSICA L?
89-93
Hyperfine interaction and crystalline environment NdTi( Fe 1_$o,) 1 1 compounds by 57Fe Mijssbauer Jifan
Hu,
Ziwen
Dong,
Yinglie
Liu
and
Zhenxi
in study
Wang
Institute of Ph,ysics, Academia Sinica, Beijing 100080, China Received 3 December 1990 Final received I7 January 1992
In this paper, the Mossbauer spectra for NdTi(Fe I XCo,),, compounds have been investigated. The hyperfine interaction has been studied with respect to the crystalline environment. The results show that cobalt atom prefers to occupy the 8f site in the range of high iron content and iron atom prefers to occupy the 8j site in the range of high cobalt content. The variations of the magnetic moments for each iron site 8i, 8j and 8f are very small with increasing cobalt content in compounds. At the step of the initial replacement of the iron atom by cobalt, the quadrupole splittings QS and isomer shift IS for the 8f site increase and for 8i decrease corresponding to the occupation preference on the iron site for cobalt atoms. Similar composition dependences of QS and IS implies that there exists a shielding effect or coupling of s-d electrons in the compounds
1. Introduction The Fe-rich compounds of the type ,zPvMg (R = rare earth, M = Ti, Cr, V, MO, RFe W) are. of the body-centered tetragonal ThMn,, structure. The large solid solution range is achieved with M =V (1.4~~ < 3.5), but quite narrow for Ti (O.S
0
1992 - Elsevier
Science
fur Metall1, W-7000
Publishers
occupation of 16k2 [9], which has a relatively small interatomic distance between 3d atoms. Such a small interatomic distance is likely to favour an antiferromagnetic interaction. The preferential site occupation on 16k, of cobalt is attributed to the relatively strong initial increase of the Curie temperature with the replacement of iron by cobalt. The most interesting case is the 57Fe Mossbauer effect on Nd,(Fe, _,Co,),,B in the range of high cobalt content for which Van Noort and Buschow [lo] and Honma et al. [9] found strong evidence for a strong preference of the Fe atoms for the 8j, site, which has a relatively large number of 3d nearest neighbours. These results are in good agreement with a neutron diffraction study of Nd,(Fe, ,Co,) ,4B by Herbst and Yelon [ll]. As we know, we can understand something about the influence of the crystalline environment on the hyperfine interaction in the compounds via the hyperfine field, isomer shift and quadrupole splitting, and to compare them with the results of magnetic measurements, neutron diffractions and band structure calculations. To obtain the relationship between the local mag-
B.V. All rights
reserved
Experiment
2.
‘l‘hc NdTi( noniinnl pdrcd 00.5
Fc,
b>
with
,C‘oi ), , compounds
composition
the
~\-= 0.09LO.S26
LVCI-c prc-
the
of
melting
clcnients
purlt!
M’t’; or bcttcr under argon atmosphcrc.
button
ingots
wcrc
melted
then
scalecl
homogeneity.
annealed tion
of
in
timcs
ThMn
;I the
bc essentially
,? tetragonal
second
phase
The
Miissbaucr-
po~~nds.
using
to
;I constant
temperature. using
of The
cr-Fe
a11
sp&tr:r
“(‘0
The
amount
in
the
wcrc
scale
with dt
;I
room
calibrated
W;I~
at room
con-
mcasurcci
palladium
velocity
absorber
the phase
spectrometer
in
and
diffrac-
;i single
small
accclcration
50 niC~‘i source
tube
indicated
of
vcrv
CI~SLII-c
X-ray
structure.
is
The
to
quartz
;I
at 900°C for two weeks. ( Co-Ka radiation) patterns
compounds with
four
tcmperaturc.
1;lllcc
3.
hcthccI1
pcrfinc ‘I‘hc with
Miissbauer
spectra
.\-= O.(W.
mcasurcci
0.775.
room
at
of
NdTi(
0.454.
Fc,
O.h32
temperature
/ <‘oi ) , ,
and
O.S2h
arc shown
in fig.
kc
ne
timely.
Results and discussion
ticid
Si
1.c
ha\c
the
the
\itc
4incc
ncarcst
ncighbour
Iarget
avci-age
smallest
e;Ich
dlou1d
;ltolll\
site
IOI
Si
nunibcl-
ot iron
ticlci should
corrq~ond
\ifC hince it ha4 the dlortcst
atomic
clistancc.
distribution
iron
hypcrfinc
broader
line
the site
environment.
shape comes
do111
distribution
has
an influence
neighhour knowlccigc
that ha5
ncighbour In this for NciTi( ments
or
Fe, were
ncighbour
the
atom
the
site.
hypedine
titanium
:I
, Co, ) , ,
of
compou~lds.
performed environment
or
the r;u-
in
shells
used
for
anal!,sis, such
and
xpectra
KFc
the
continuou\ a
assign-
table
the
nearest
ments
dis-
ing
the
had been
INII
the St
“Fc
a11d
With
Miissbaucl
successf’ully
cur\ c through
tit to the of
quadrupole
i-clati\e
both
caih
In
fitted
[ 121.
reprcscntk
tf,,,.
,,,\I,
tor
for the Si 5itc.
of’ assignment.
for
previously
~uby~ectrum
one
kind
a
t Iic
r:e- l-‘c Intel
in fitting.
arc for
the> 10
5ubspectra
to be introduced
~MO subhpcctra
\itt‘\
Xj
site
the interatomic
haI
parameters
[ 12. 1.31. was
Gtc
The
nearest
spectra The
the
decreaw~ the
method
the
which
next-nearest
ticki
considering and
;I
01
considering
atoms
least-squares
fitting
from
at the tii site
nenrcst
iron
Such
the multiplicit?
next-neighbour
work.
computer
on each
when
from
[4],
It originates
of Ti
for
iron
fields
II\-
largc>\t
atom5 2nd the
St’ iron
of
the
nieanwhilc
1. The outer lines of the spectra arc broadci- than t hc inner 011~5. indicating that there exists ;I
I ip to tucl
rc~pcc
Iargc41
has
fccaPte cli4t;incc.
hi pcrtinc
4ltC’.
intcnsit\
the
for
OS. cad1
I. Wc try to derive of the F;e \ublatticcs
hvpcrfinc
The
\ubspectra.
splitting I
the data point\
spectrum.
tietcia. ‘l‘hc
isomer iron
site
average from
hypcrlinc
hyperfine
licld
diift
IS
and
art‘ listed
niiignctic
ii) ilio-
the corrcspon&
approximation
xhoulrl
.I. Hu et al.
I ‘?Fe Miissbauer studies on NdTi(Fe,
be made for the hyperfine interaction constant, the proportional factor between the average iron moment of the alloy and the average hyperfine field. Here, we adopt a proportional factor of 15.6T/p., derived from ref. [13]. The composition dependence of the average hyperfine field and the average magnetic moment of iron atoms for NdTi(Fe,_.Co,), , system are shown in fig. 2. One can clearly see that with the replacement of the iron by cobalt, the average hyperfine field as well as the average iron magnetic moment increases at first. and then decreases. The peak point appears at about x = 0.27. It is interesting to point out that a maximum at about x = 0.27 for the saturation magnetization in RTi(Fe,_,Co,),, has also been found by Sinha et al. from magnetization measurements [a]. It implies that besides the effect of the relative small magnetic moment of the cobalt sublattice. the change of the magnetic moment of the iron sublattice also plays an important role in the total saturation magnetization M, of the RTi(Fe, _rC~x)l, system. A maximum when present at low temperature T = 4.2 K for Fe-Co based magnetic materials can be easily explained by the process of electron transfer between the 3d spin up and spin down energy band. However, at high temperature, such as room temperature, the effect of electron transfer
>Co,),,
0.00
0.20
compounds
0.40
X
91
0.60
x = 0.092
x = 0.275
x = 0.459
x = 0.642
x = 0.826
8i Xj Xf Xi 8j 8f 8i 8j 8f 8i *j 8f 8i 8j 8f
-0.024 -0.134 -0.124 -0.038 -0.131 -0.111 -0.004 -0.045 -0.086 -0.100 -0.022 -0.135 -0.050 -0.007 -0.094
for a similar maximum is not so clear due to the complicated temperature dependence of the 3d spin up and spin down energy band. When considering the composition dependence of the magnetic moment for each iron site 8i, Sj and 8f, shown in fig. 3, it seems that the variation of the magnetic moment is very small, which can be only called as some kind of fluctuation. In such case, it is not easy to understand why there is such a maximum. We can only say that the maximum may be originates from the counteracting effects of the increase of Curie temperature T, and the decrease of 3d sublattice magnetization with increasing the cobalt content. The composition dependence of the iron occu-
QS (mm/s)
-0.124 -0.175 -0.118 -0.024 -0.084 0.010 -0.064 -0.050 -0.031 -0.032
1.00
Fig. 2. The composition (x) dependence of the average hyperfine field (H,,) and the average iron atom magnetic moment (MFc) for the NdTi(Fe,_,c~~),, system.
Table 1 Isomer shift IS, quadrupole splitting QS, hyperfine field H,, and relative intensity I of each of the subspectra sites Si, Sj and 8f in the NdTi(Fe,_,Co,),, compounds with x = 0.092, 0.275, 0.642 and 0.826. IS (mm/s)
0.80
0.098 0.056 0.093 0.089 0.002 0.098 0.027 0.100 0.166 -0.154 0.016 0.078 0.058 -0.053 0.168
0.086 0.279 0.103 0.166 0.042 0.065 0.074 0.232
30.6 27.6 22.4 30.3 27.8 23.0 31.2 28.5 22.7 31.1 28.3 23.3 31.3 28.7 23.1
iron
I (%
H,,(T) 0.080 0.026
for the three
25.2 18.9 25.7 20.5 25.5 20.2 26.1 20.3 25.8 19.7
36 20 20 37 13 17 20 29 12 10 27 30 5 13 28
21 3 2x 5 34 5 26 7 49 5
‘I he
‘xullposItlon
depe11dc11ce
splitting
rup’)Ic
(C)S)
qC’(jt 1,
1hc
‘,I
col~~llt
MC’
~211
I-;ingc 0,.?75.
\
cx~ntrar\
. QS( SI )
1
only range
content
l’or
three
ircjn
i),(145. WC thinh. cxntial in fig.
4.
the
We
Sf Gte
f-c prcfcI-s the
each iron
A
result
interaction. the
the
(‘ohnit. ;I
1:ehavioIof
the St atoms the distance
a
larger of
relative
i4
ma>
the
increases. increases
rapidly
of iron
lw cobalt.
WC
antiferromagncti~,
Thercforc.
interaction
the with
the
Curie initial
tenrc‘-
on
of the
St
QS
clecrcascs.
With
tent.
Si
the
tion NdTi(
PC,
the
the
XI
atom
will
ix
1’
that
\alcncc
the
contribution
QS
t’)
>ysem
cjt‘ CjS Iv
incrcaes
sites
coI;p’ment
lcurthcrniorc. 01 clcctric
hb to
-incre;isc tountl conIp<>\~-
the niainl\~
/I1
field
the
clrtcI-Ininccl
of the- c.lcctric wc want
III
replaccIncIIt atoll1
term
CX)I~
cobalt.
The
cobalt
is
SI and Si
been
[“I.
with ;I
to the clcctric
cbcculxclu;~ci~-upolc
of the cxAxrlt
have
I
i\ I’) w\
(Kf).
bcgina
data )i ,B
4plittIn~
That the
the
and thc*lI
the prelcl-
occupied
, (‘0, ) i ! 4vsteni
principal
with
hits.
cohall
O.S1h. first
\ =z 0.002
cohalt.
‘111~1
In the
t hc preferential
QS( Si )
gradient
111c1-c;Iw
accord
i1.011 \Itc.
5itc
Fe / ,(‘o, iron
\
to \
the increasing
clep~ndencc the
I\1
from
ot
experimental
Nd,(
the
1177.q
tkm
t”)r the unoccupied
~oI-I-cspondin~l~. Similar
the
In
01 the cluaclrupolc
to
cotwIt
On
dccreaw
)
0 IFI
‘wulxrtion
Meanwhile.
t)l
ciecre~rscs and
fcrromagnctic
hchavior
site.
01
4plittIng
‘)t
excha~igc
the Xf iron
tion
the
amdlcr
magnetic
on the Xf site
the
intc‘r-
of an antiferromagneti~
pcrature placement
Xj)
to occupy
prcqx)rtion
Fe-Fc
In
4itc
c’~rresponciin~
t hal.
and
content.
t-‘c-Fe distance
with
and
prefers
pl-oportion
content
between
;I short
i\ shoun to occup>
iron
shortest
A.
occurrcncc
radius.
interaction
of high the
is 2.392
Such
interaction.
thinh
Co prefers
St‘) and Ftz( Xf)-Fe( 141.
in the
atomic
Sj and tif.
in the high cobalt
4ysteni.
distance
I;c( St’-Fc( 7.454
that
range
to Sj site
KFc,,I‘i
atomic
can SW
in the
Si.
site,
1’1
quadrupol~~
ttlc
4itc4 decrease\
pcrhap\
III
incrcax.\.
CjS(Si)
\ite\
III
5.
O.O’C
\
tlecre~iacs.
\
ir’)n
‘I‘hc trends
the
Si
:incf
QS( Si) trc)ni
CJS ot all three incI-c;isc\.
C_K(
c0nte11t
QS( Xi)
11.159.
only
Gtc
iu liy.
fr0111
that
quad
iron
I\ 4houn
OS(H).
:incl
~x,h;llt
the
incanwhilc
for
~c’c’
ol the St \itc.
ot
each
c011te11t
splitting
l~allgc
pation
\v\lcni
NdI’i(I-c!
the
ot
tor
to p’jirit gI\c\
grxlient
field ou1
(El-G I
J. Hu et ul. I ‘7Fe Mhshauer
studies on NdTi(Fe,
-01
Fig. 6. The composition (x) dependence of isomer for each iron site 8i. 8j and 8f in the NdTi(Fe, system.
shift IS rCo,),,
shift (IS) for each iron site in the system are shown in fig. 6. NdTi(Fe,_,Co,),, The isomer shift IS of the Mossbauer spectrum for “Fe is proportional to the local electronic charge density p(O) at the “Fe nuclear position and therefore is related to the spatial distribution of the electrons surrounding the nuclei. The electron distribution can change not only with a change in the number and character of electrons but also with a surrounding the 57Fe nuclei, change in the distribution of the nearest neighbours of the iron atom. The isomer shift is essentially determined by the number of s-electrons of the nearest-neighbor iron atom. From fig. 6, one can easily see that the isomer shift of 8f increases (the absolute value of the negative IS decreases) with the initial preferential occupation by cobalt atom on the 8f site, which is very similar to the results of calculations and experiments on the system of Co-impurity in Fe [14]. It may be implies that the number of s-like electrons at the 8f iron site decreases in this case. Meanwhile, from fig. 6 we can also see that the IS of 8i decreases and the IS of 8j increases slightly with the initial increase of the cobalt content in the compound. We do not know
I Co<),, compounds
93
exactly in this case how much the local d charge or the intra-atomic screening affect the IS. Comparing the composition dependence of quadrupole splitting QS and isomer shift IS in the range of small content of cobalt atoms in compounds, it is very interesting to find that two dependences are somewhat similar. It implies that there exists a shielding effect or a coupling of s-d electrons. However, since the relative accuracy of the values of the quadrupole splitting and the isomer shift are less than that of the hyperfine held and there exist four types of atoms (Nd, Ti, Fe and Co) in compounds, the complications of the shielding effect of s-d electrons increase. Speaking frankly, to give an exact analysis on the density of s or d electric charge at such case is almost impossible.
References
[II
D.B. de Mooij and K.H.J. Buschow, J. Less-Common Metals 136 (1988) 207. PI Jifan Hu, Tao Wang. Shougong Zhang, Yizhong Wang and Zhenxi Wang, J. Magn. Magn. Mater. 74 ( 1988) 22. PI R.B. Helmholdt, J.J.M. Vleggaar and K.H.J. Buschow. J. Less-Common Metals 138 (1988) Ll 1. [41 0. Moze, L. Pareti, M. Solzi and W.I.F. David. Solid State Commun. 66 (1988) 465. D.B. de Mooij and [51 F.R. de Boer. Huang Ying-Kai. K.H.J. Buschow, J. Less-Common Metals 135 (1987) 199. VI Jifan Hu, Yizhong Wang, Ruwen Zhao, Taishan Ning, Zhenxi Wang, Solid State Commun. 70 (1989) 983. [71 K.H.J. Buschow. J. Appl. Phys. 63 (1988) 3130. [81 V.K. Sinha. S.F. Cheng, W.E. Wallace and S.G. Sankar. J. Magn. Magn. Mater. 81 (1989) 227. PI H. Honma and H. Ino, IEEE Trans. Magn. MAC-23 (1987) 3116. [lOI H.M. Van Noort and K.H.J. Buschow. J. Less-Common Metals 113 (1985) L9. [Ill J.F. Herbst and W.B. Yelon. J. Appl. Phys. 60 (19X6) 4224. iI21 A. Deriu. G. Leo. 0. Moze, L. Pareti. M. Solzi and K.H. Xue, Hyperfine Interactions 45 (1989) 241. [13] Bo-Ping Hu. Hong-Shou Li and J.M.D. Coey, Hyperfine Interactions 45 (1989) 233. [ 141 P.H. Dederichs, R. Zeller, H. Akai and H. Ebert. J. Magn. Magn. Mater. 100 (1991) 241.