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Insertion of bi-valence cations Mg2+ and Zn2+ into V2O5
~
Solid State Communications, Printed in Great Britain.
Vol.61,No.5,
pp.27]-273,
1987.
0038-|098/87 $3.00 + .00 ~ 1 9 8 7 Pergamon Journals Ltd.
INSERTION OF ~I-VALENCE CATIONS Mg2~ AND Zn 2+ INTC V205 Wen-hal Yu, Da-zhi Wang, Bin Zhu*, Shen-jun Wang and Li-xin Xus (University of Science and Technology of China, ~efei, Anhui, China) (Received 26 September
1986 by W.Y. Kuan)
ABSTRACT: The fresh cross sections of the interface between Mg- or Zn-montmorillonite as a solid electrolyte and V205 as a cathode in MgtV205
or ZnIV205 cell have been investigated
by SEM and EMP.
It
is shown that the bi-valence cations Mg 2÷ and Zn 2+ also can be inserted into V205 and give a conclusive evidence on migration of ~g2+ and Zn 2+.
A number of cathode materials
works on insertion of single-valence cathode materials
such as TiS 2,
interface between Mg- or Zn-montmoriIlonite
for rechargeable
solid batteries have been investigated
and many
cations into
observed
V205, V}O8, V6015
on scanning electron microscope
well as electron microprobe microscope.
etc. have been reported 1'2. Recently,
(EMP) by X-650 electron
Photo I is the SEM image for cell A before dis-
we have found that the bi-valence
V205.
It has been reported that montmorillonite,
which
is provided with a better ionic exchangeability conductivity,
and
can be used in solid state batteries
as a solid electrolyte 3 .
Ng- and Zn-montmoril]onite
have been used to assembly two kinds of solid cells as following: A.
Mg t Mg-montmorillonite
p V205
B.
Zn P Zn-montmorillonite
p V205
The p±operties
of charge and discharge for these
cells are very good as shown in Table I. To investigate whether Mg 2+ and Zn 2+ might be inserted
into V205,
the fresh cross section of the
Table I.
Cell
properties of discharge average current cut off capacity (~A) volta6e (V) (mAh)
cell area (gm 2)
(A)
1.5
26
1.0
8.0
1.55
(B)
1.1
28
0.9
5.7
1.53
voltage (V)
*University
Fig. 1
Properties of charge and discharge for (A) MgPV205 and (B) Zn'V20 ~ cells
average voltage (V)
cyclic properties of charge-discharge current (~A) deep of charge-discharge charge-discharge
1.5
50
2o %
1.2
50
10 %
of Science and Technology
(SEM) as
The results are shown in Photo I to 4.
cations Mg 2+ and Zn 2+ also can be inserted into the cathode
and
V205 in these cells before and after discharge were
15 25
of Staffs and Workers of Hefei 271
cycles
272
INSERTION OF FI-VALENCE CATIONS Mg2+AND Zn 2+ INTO V205
Vol. 61, No. 5
charge, the left is V205 and the right is Mg-montmorillonite.
The EMP analysis on Mg content has
been carried out along line AA'
It is found that
the distribution of Mg content displays a jump at the interface.
In the side of V205, Mg content is
approximatly zero, and on other side of Mg-montmorillonite,
it shows a maximum near the interface
and decrease gradually with the increasing of the distance from the interface. Photo 2 is the result of EMP analysis on Mg con-
Fig. 3
Fig. 2
tent for cell A after discharge.
It is apparent
that magnesium has gone far into V205 and its content decrease with the increasing of the distance from the interface.
Fig. 4
The EMP analysis on V and Si
content also has been carried out along same line. It is obvious that the distribution of Si, which is the characteristic
element of montmoriilonite,
and
Table 2 shows the results of XRD analysis for V205 before and after discharge.
It is
that of V, which is the characteristic element of
exhibited that the lattice has been expanded
V205, are provided with the relation of complement
because of the insertion of Mg and Zn into
each other.
V205 •
Then the interface is shown clearIy
therefrom.
By above-mentioned
Photos 3 and 4 are the results of EMP analysis for cell B before and after discharge, PB' is
inltia] results, it is
shown that V205 also can be inserted by bivalence cations Mg 2+ and Zn 2+ and form some
scanning lime, and the results are slmiffar to
inserted compounds.
that from Photos I and 2.
the insertion of Li + cation into V20~4.
Table 2.
This is similar to that
Change of the eharactiristic interplanar distance in V205 before and after discharge hkl
200
001
110
011
400
002
5.758
4.372
3.403
2.762
2.880
2.184
d (after inserting of Mg)
5.784
4.~84
3.422
2.768
2.886
2.187
d (after inserting of Zm)
5.825
4.409
3.422
2.777
2.896
d (before discharge)
Vo[. 6], No. 5
INSERTION OF ~I-VALENCE
CATIONS Mg2+AND Zn 2+ INTO V205
273
References:
I.
D. W. Murphy, Solid State lonics 18 & 19 (I 986), 847.
2.
5.
Publishing, 4.
io68.
Da-zhi Wang et al, in " Materials for Solid State Batteries
1986 " ed. by B. V. R.
Chowdar± and S. Radhakrishna,
R. Kanno et al, Solid State Ionics 18 & 19 (1986),
Workshop, Singapore,
-- Proceedings
of the Regional
Singapore,
World Scientific
1986, p. 461.
B. Monisha, Solid State Ionics 18 & 19 (1986),
902.
Solid State Communications, Printed in Great Britain.
Vol.61,No.5,
pp.27]-273,
1987.
0038-|098/87 $3.00 + .00 ~ 1 9 8 7 Pergamon Journals Ltd.
INSERTION OF ~I-VALENCE CATIONS Mg2~ AND Zn 2+ INTC V205 Wen-hal Yu, Da-zhi Wang, Bin Zhu*, Shen-jun Wang and Li-xin Xus (University of Science and Technology of China, ~efei, Anhui, China) (Received 26 September
1986 by W.Y. Kuan)
ABSTRACT: The fresh cross sections of the interface between Mg- or Zn-montmorillonite as a solid electrolyte and V205 as a cathode in MgtV205
or ZnIV205 cell have been investigated
by SEM and EMP.
It
is shown that the bi-valence cations Mg 2÷ and Zn 2+ also can be inserted into V205 and give a conclusive evidence on migration of ~g2+ and Zn 2+.
A number of cathode materials
works on insertion of single-valence cathode materials
such as TiS 2,
interface between Mg- or Zn-montmoriIlonite
for rechargeable
solid batteries have been investigated
and many
cations into
observed
V205, V}O8, V6015
on scanning electron microscope
well as electron microprobe microscope.
etc. have been reported 1'2. Recently,
(EMP) by X-650 electron
Photo I is the SEM image for cell A before dis-
we have found that the bi-valence
V205.
It has been reported that montmorillonite,
which
is provided with a better ionic exchangeability conductivity,
and
can be used in solid state batteries
as a solid electrolyte 3 .
Ng- and Zn-montmoril]onite
have been used to assembly two kinds of solid cells as following: A.
Mg t Mg-montmorillonite
p V205
B.
Zn P Zn-montmorillonite
p V205
The p±operties
of charge and discharge for these
cells are very good as shown in Table I. To investigate whether Mg 2+ and Zn 2+ might be inserted
into V205,
the fresh cross section of the
Table I.
Cell
properties of discharge average current cut off capacity (~A) volta6e (V) (mAh)
cell area (gm 2)
(A)
1.5
26
1.0
8.0
1.55
(B)
1.1
28
0.9
5.7
1.53
voltage (V)
*University
Fig. 1
Properties of charge and discharge for (A) MgPV205 and (B) Zn'V20 ~ cells
average voltage (V)
cyclic properties of charge-discharge current (~A) deep of charge-discharge charge-discharge
1.5
50
2o %
1.2
50
10 %
of Science and Technology
(SEM) as
The results are shown in Photo I to 4.
cations Mg 2+ and Zn 2+ also can be inserted into the cathode
and
V205 in these cells before and after discharge were
15 25
of Staffs and Workers of Hefei 271
cycles
272
INSERTION OF FI-VALENCE CATIONS Mg2+AND Zn 2+ INTO V205
Vol. 61, No. 5
charge, the left is V205 and the right is Mg-montmorillonite.
The EMP analysis on Mg content has
been carried out along line AA'
It is found that
the distribution of Mg content displays a jump at the interface.
In the side of V205, Mg content is
approximatly zero, and on other side of Mg-montmorillonite,
it shows a maximum near the interface
and decrease gradually with the increasing of the distance from the interface. Photo 2 is the result of EMP analysis on Mg con-
Fig. 3
Fig. 2
tent for cell A after discharge.
It is apparent
that magnesium has gone far into V205 and its content decrease with the increasing of the distance from the interface.
Fig. 4
The EMP analysis on V and Si
content also has been carried out along same line. It is obvious that the distribution of Si, which is the characteristic
element of montmoriilonite,
and
Table 2 shows the results of XRD analysis for V205 before and after discharge.
It is
that of V, which is the characteristic element of
exhibited that the lattice has been expanded
V205, are provided with the relation of complement
because of the insertion of Mg and Zn into
each other.
V205 •
Then the interface is shown clearIy
therefrom.
By above-mentioned
Photos 3 and 4 are the results of EMP analysis for cell B before and after discharge, PB' is
inltia] results, it is
shown that V205 also can be inserted by bivalence cations Mg 2+ and Zn 2+ and form some
scanning lime, and the results are slmiffar to
inserted compounds.
that from Photos I and 2.
the insertion of Li + cation into V20~4.
Table 2.
This is similar to that
Change of the eharactiristic interplanar distance in V205 before and after discharge hkl
200
001
110
011
400
002
5.758
4.372
3.403
2.762
2.880
2.184
d (after inserting of Mg)
5.784
4.~84
3.422
2.768
2.886
2.187
d (after inserting of Zm)
5.825
4.409
3.422
2.777
2.896
d (before discharge)
Vo[. 6], No. 5
INSERTION OF ~I-VALENCE
CATIONS Mg2+AND Zn 2+ INTO V205
273
References:
I.
D. W. Murphy, Solid State lonics 18 & 19 (I 986), 847.
2.
5.
Publishing, 4.
io68.
Da-zhi Wang et al, in " Materials for Solid State Batteries
1986 " ed. by B. V. R.
Chowdar± and S. Radhakrishna,
R. Kanno et al, Solid State Ionics 18 & 19 (1986),
Workshop, Singapore,
-- Proceedings
of the Regional
Singapore,
World Scientific
1986, p. 461.
B. Monisha, Solid State Ionics 18 & 19 (1986),
902.