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Investigation of the local geometry of Ni2+ ions in an Al2O3 crystal from EPR data
Investigation of the local geometry crystal from EPR data Zheng
Wen-Chen
The electron paramagnetic resonance (EPR) parameters D. g,, and Q (=g,, - g i ) for Ni” in corundum (Al-O,) were measured by Marshcll and coworkers [ I.21 several decades ago. but until now no satisfactory theoretical explanation related to the structural data has been made for these parameters. Marshell et al. [I] thought that a satisfactory explanation for these parameters must be based on a reasonable consideration of the local lattice distortion produced by the substitution of Ni’& for an Al” ion. However. the details of this distortion were not shown. In this paper, we will study the distortion by fitting the theoretical values of EPR parameters to the observed values. The reasonableness of this distortion is also discussed. The theoretical calculation rests on high-order perturbation formulas based on the ‘quasi-intermediate-field’ approach [3]. Thus, for a Ni‘ ’ ion in trigonal symmetry [3]. we have
’ Addrex~
of Ni’ ’ ions in an Al@,
i1XV3Bk&’ + w,w,w,
@
tYYi - Etsevwr
Science Publlshcr\
6Bkf Amwtw.
17!
where W, (i = I-S) are detined in ret. l_Jj. 3, 2.0023. u and U’ arc the trigonal field paramc-tcrs. From the point-charge model. wc ha\c
for correyx~ndence
0~~1t-~51h/Y3~$06.00
17Bk<’ w, w, w,~
B.V. All rights rewrv&
Zheng Wen-Chen
u’ =
z
3vT2 ~eq(‘*)(3cos20i
XL
I Displacement of Ni”
- 1)/R?
I=1
5v2 - 168 eq ( r”) (35 cos”@ - 30 cos’f3, + 3) /R;S -&eq(r4)sin’OjcosOjcos3~i/R~
1,
(5)
where q is the effective charge of ligand. R,, 0, and & are the structural parameters of the studied crystal. For the Al’+ site of the A&O, crystal [4], R, = 1.966 A, R, = 1.857 A, 19,= 47.7”, 0, = 63.1”, 4, = 0 and & = 4.13”. Utilizing the empirical d-orbit of the Ni2+ ion [5] and introducing a parameter N (k = N*) to denote the average covalency reduction effect, we have B = 1208N4 cm-’
,
C ==4459N4cm-’
.$ = 636N’cm-’
,
(r*)
= 1.8904N’
a.u. ,
(r’)
= 13.4043N’
a.u.
,
(6)
The parameter N is determined from the optical absorption spectra of the studied crystal. According to the optical spectra of the Al,O, : Ni’+ obtain N -0.964, Dq -‘I crystal [6], we The comparison of optical spectra 1000 cm-‘. between calculation and experiment is shown in table 1. Thus, the adjustable parameter q can be obtained from the parameter Dq by using the formula 3ti 2 Dq = - 16 eq (Ir4) c sin”tl; cos 0, cos 3&lRj . (7)
1=I
Table 1 Cubic theoretical values and experimental data for the optical absorption spectra of an AlzO, :Ni” crystal. Theory Energy
‘A,(‘F) ‘T2(‘F)
0 10 000
‘E(D) ‘T,(‘F)
15 467 16560
“‘Ref.
[6]
(cm-‘)
Level
Energy
‘A,(‘A>) ‘A,(‘Tz) ‘E, ‘T>) ‘E( ‘E) ‘AZ(3T,) ‘E( ‘T, )
0 10 500 9800 15 800 16 590 16 500
(cm-‘)
323
Substituting the parameters N, q and the structural data related to the exact Al”+ site in Al,O, into the above formulas, we can calculate the EPR parameters D, g,, and Ag. They are compared with the observed values in table 2. It can be seen that the calculated EPR parameters (particularly the zero-field splitting D and the parameter Ag) based on the structural data of the host crystal are indeed in disagreement with the observed values. So, the local lattice distortion produced by the substitution of Ni2+ for the Al”+ ion should be taken into account. The EPR experiments [1,2] indicate that the Ni’+ center in Al,O, still has a trigonal symmetry; we therefore assume that the Ni*+ ion is displaced along the C, axis from the exact site of the replaced Al” ion (note: for simplicity, the positions of oxygen ligands are assumed to be unchanged). Considering that the calculated values of 1DI and Ag are greater than the observed values, to reach a good fit between theory and experiment, the Ni’+ ion should be shifted towards the central site of the oxygen octahedron, which results in a smaller trigonal distortion and hence the smaller calculated values of IDI and Ag. The quantitative calculation shows that the displacement of the Ni’+ ion is 0.05 A. The comparison between calculation and experiment is shown in table 2. Noteworthily, the above displacement direction is reasonable in physics. As is known, the Al,O, lattice can be visualized as a stacking of equidistant oxygen planes perpendicular to the C, axis. The oxygens are arranged in a triangular lattice and form an almost hexagonal closepacked structure. Along the C, axis, the oxygens Table 2 EPR parameters
of an AlzO,
: Ni’ ’ crystal.
Calculation
Experiment”’
Level
in Al,O,
D (cm-‘) & 4
Experiment
1J,
IIh’
I”
-2.3972 2.2245 0.0181
-1.3108 2.2160 0.0099
-
IId’
1.3760 2.1957 0.0098
- 1.3287 2.196 0.009
“‘Calculated from the structural data of the host crystals. “‘Calculated by taking into account the impurity displacement AZ = 0.05 A. “Ref. [ 11. “‘Ref. [2].
constitute
a sequence
of
distorted
octahedra.
successively containing Al” , Al” ions vacant site. The electrostatic repulsive
ions displaces these cat-
between the two Al’ ions from the midway layers
and leads
schematic cations
view
the oxygen
to the positions closer vacancies.
of
the
oxygen
is shown between
cation i\ replaced hy
an
plancs
in fig. these
electrostatic
the
upon
between
to A
neighbouring
included
the separation
plane
them
distinctive
tk
and a force
cations
repulsive impurity
the
and
1. Obviously, force.
&pen& If
the
having different
charge. it can be expected that the impurity ion dots not occupy the exact site of the replaced Ali’
ion, but is displaced along the c’; axis by
amount the ion.
AZ hccause
impurity In
differs
general.
the repulsive from when
force acting
an
charge
than
the
replaced
ion.
host
the
C~C‘C‘II-o-
static repulsive force acting on the impurity i4 smaller than that on the host ion and the imput-ity should
bc shifted
towards
the
plant
midway
bctwecn oxq’gcn layera. whereas. fog- the impurity carrying tion
with
extra
rehpcct
bccaLlac
of
force.
the
OhviousIy.
charge.
the displacement
larger for
electrostatic the
direc-
plane ih opposite
to the midway
repukivc
Ni”
AI,O,:
crystal.
the ~~bovc clisplacemcnt tiircction of the Ni’ is consistent with what WC‘ expect and can regarded that
physically
as
by studying
the
reasonable. EPK
infol-mation about the lc~al impurity ion cm be obtained.
data.
It
bc
appears
some
gcometr!
ion
useful
of
the
on
that on the host Al’ the
impurity
has
Icss
Acknowledgement ‘lliia
proJect
Foundation tee of (‘hina I<‘MP!92iO.3).
References
LV;I\ \upportcd
of the National
134’ the Education
and the Foundation
Science (‘ommit-
of ICMP
(no.
Wen-Chen
The electron paramagnetic resonance (EPR) parameters D. g,, and Q (=g,, - g i ) for Ni” in corundum (Al-O,) were measured by Marshcll and coworkers [ I.21 several decades ago. but until now no satisfactory theoretical explanation related to the structural data has been made for these parameters. Marshell et al. [I] thought that a satisfactory explanation for these parameters must be based on a reasonable consideration of the local lattice distortion produced by the substitution of Ni’& for an Al” ion. However. the details of this distortion were not shown. In this paper, we will study the distortion by fitting the theoretical values of EPR parameters to the observed values. The reasonableness of this distortion is also discussed. The theoretical calculation rests on high-order perturbation formulas based on the ‘quasi-intermediate-field’ approach [3]. Thus, for a Ni‘ ’ ion in trigonal symmetry [3]. we have
’ Addrex~
of Ni’ ’ ions in an Al@,
i1XV3Bk&’ + w,w,w,
@
tYYi - Etsevwr
Science Publlshcr\
6Bkf Amwtw.
17!
where W, (i = I-S) are detined in ret. l_Jj. 3, 2.0023. u and U’ arc the trigonal field paramc-tcrs. From the point-charge model. wc ha\c
for correyx~ndence
0~~1t-~51h/Y3~$06.00
17Bk<’ w, w, w,~
B.V. All rights rewrv&
Zheng Wen-Chen
u’ =
z
3vT2 ~eq(‘*)(3cos20i
XL
I Displacement of Ni”
- 1)/R?
I=1
5v2 - 168 eq ( r”) (35 cos”@ - 30 cos’f3, + 3) /R;S -&eq(r4)sin’OjcosOjcos3~i/R~
1,
(5)
where q is the effective charge of ligand. R,, 0, and & are the structural parameters of the studied crystal. For the Al’+ site of the A&O, crystal [4], R, = 1.966 A, R, = 1.857 A, 19,= 47.7”, 0, = 63.1”, 4, = 0 and & = 4.13”. Utilizing the empirical d-orbit of the Ni2+ ion [5] and introducing a parameter N (k = N*) to denote the average covalency reduction effect, we have B = 1208N4 cm-’
,
C ==4459N4cm-’
.$ = 636N’cm-’
,
(r*)
= 1.8904N’
a.u. ,
(r’)
= 13.4043N’
a.u.
,
(6)
The parameter N is determined from the optical absorption spectra of the studied crystal. According to the optical spectra of the Al,O, : Ni’+ obtain N -0.964, Dq -‘I crystal [6], we The comparison of optical spectra 1000 cm-‘. between calculation and experiment is shown in table 1. Thus, the adjustable parameter q can be obtained from the parameter Dq by using the formula 3ti 2 Dq = - 16 eq (Ir4) c sin”tl; cos 0, cos 3&lRj . (7)
1=I
Table 1 Cubic theoretical values and experimental data for the optical absorption spectra of an AlzO, :Ni” crystal. Theory Energy
‘A,(‘F) ‘T2(‘F)
0 10 000
‘E(D) ‘T,(‘F)
15 467 16560
“‘Ref.
[6]
(cm-‘)
Level
Energy
‘A,(‘A>) ‘A,(‘Tz) ‘E, ‘T>) ‘E( ‘E) ‘AZ(3T,) ‘E( ‘T, )
0 10 500 9800 15 800 16 590 16 500
(cm-‘)
323
Substituting the parameters N, q and the structural data related to the exact Al”+ site in Al,O, into the above formulas, we can calculate the EPR parameters D, g,, and Ag. They are compared with the observed values in table 2. It can be seen that the calculated EPR parameters (particularly the zero-field splitting D and the parameter Ag) based on the structural data of the host crystal are indeed in disagreement with the observed values. So, the local lattice distortion produced by the substitution of Ni2+ for the Al”+ ion should be taken into account. The EPR experiments [1,2] indicate that the Ni’+ center in Al,O, still has a trigonal symmetry; we therefore assume that the Ni*+ ion is displaced along the C, axis from the exact site of the replaced Al” ion (note: for simplicity, the positions of oxygen ligands are assumed to be unchanged). Considering that the calculated values of 1DI and Ag are greater than the observed values, to reach a good fit between theory and experiment, the Ni’+ ion should be shifted towards the central site of the oxygen octahedron, which results in a smaller trigonal distortion and hence the smaller calculated values of IDI and Ag. The quantitative calculation shows that the displacement of the Ni’+ ion is 0.05 A. The comparison between calculation and experiment is shown in table 2. Noteworthily, the above displacement direction is reasonable in physics. As is known, the Al,O, lattice can be visualized as a stacking of equidistant oxygen planes perpendicular to the C, axis. The oxygens are arranged in a triangular lattice and form an almost hexagonal closepacked structure. Along the C, axis, the oxygens Table 2 EPR parameters
of an AlzO,
: Ni’ ’ crystal.
Calculation
Experiment”’
Level
in Al,O,
D (cm-‘) & 4
Experiment
1J,
IIh’
I”
-2.3972 2.2245 0.0181
-1.3108 2.2160 0.0099
-
IId’
1.3760 2.1957 0.0098
- 1.3287 2.196 0.009
“‘Calculated from the structural data of the host crystals. “‘Calculated by taking into account the impurity displacement AZ = 0.05 A. “Ref. [ 11. “‘Ref. [2].
constitute
a sequence
of
distorted
octahedra.
successively containing Al” , Al” ions vacant site. The electrostatic repulsive
ions displaces these cat-
between the two Al’ ions from the midway layers
and leads
schematic cations
view
the oxygen
to the positions closer vacancies.
of
the
oxygen
is shown between
cation i\ replaced hy
an
plancs
in fig. these
electrostatic
the
upon
between
to A
neighbouring
included
the separation
plane
them
distinctive
tk
and a force
cations
repulsive impurity
the
and
1. Obviously, force.
&pen& If
the
having different
charge. it can be expected that the impurity ion dots not occupy the exact site of the replaced Ali’
ion, but is displaced along the c’; axis by
amount the ion.
AZ hccause
impurity In
differs
general.
the repulsive from when
force acting
an
charge
than
the
replaced
ion.
host
the
C~C‘C‘II-o-
static repulsive force acting on the impurity i4 smaller than that on the host ion and the imput-ity should
bc shifted
towards
the
plant
midway
bctwecn oxq’gcn layera. whereas. fog- the impurity carrying tion
with
extra
rehpcct
bccaLlac
of
force.
the
OhviousIy.
charge.
the displacement
larger for
electrostatic the
direc-
plane ih opposite
to the midway
repukivc
Ni”
AI,O,:
crystal.
the ~~bovc clisplacemcnt tiircction of the Ni’ is consistent with what WC‘ expect and can regarded that
physically
as
by studying
the
reasonable. EPK
infol-mation about the lc~al impurity ion cm be obtained.
data.
It
bc
appears
some
gcometr!
ion
useful
of
the
on
that on the host Al’ the
impurity
has
Icss
Acknowledgement ‘lliia
proJect
Foundation tee of (‘hina I<‘MP!92iO.3).
References
LV;I\ \upportcd
of the National
134’ the Education
and the Foundation
Science (‘ommit-
of ICMP
(no.