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The mechanism of the reaction of Ag(II) with hydrogen peroxide: An Ag2+HO2− complex
tNORG.
NUCL.
CHEM.
LETTERS
vol.
5,
pp.
9-12,
1969.
THE mECHANI5~I OF THE REACTION HYDROGEN by Department
PEROXIDE C.F.
Pergemn~, Presl.
OF Ag(ll)
AN Ag2+H02
:
Wells
and
Printed
Greet
Brlta;n.
WITH
COMPLEX
D. Mays
of Chemistry,
University
of Birmingham,
P.O.
Birmingham
15,
Box 363,
In
Edgbaston,
England.
(Received 2 November 79~)
The rate of oxidation of the same order much
faster
latter
than that
by Co(III)
m n+ second
the presence
except
whether
possibly
with mn(III), order
tified
they
with
first
a very high
mn3+OH - (K ~
mn~
in
the oxidation
order
and
high
[H202]
(5),
(6).
However,
[H202],
:
the
to determine
of FMn(III)],
(1)
is
mn+H02 - is established
the rate determining inner-sphere
electron
the first
step is identransfer
l, with
equilibrium /~
via
2 and 3.
constant
The h i g h value
ions) :
is comparable both arise
H02 aq
for the electronic
1 for
the
for Mn3+H02 - ( K > 5 x lO 16 ~.mole
&.mole -1 ) (7) +
Mn 2+ + HO 2.
\ tendency
are observed,
is independent
the separated
1014
With
and
formation
from
(3).
are observed,
equilibrium
calculated
(1) but
kinetics
for mn3+H02
formation
by mn(III)
kinetics
at very
mn3+H02 ~ constant
Ag(II)
(4) it is not possible
Fe(III)
and acidity
as the first
order
participate
order
rate constant
!Mn(II)!
(2)
by
(2) and Fe(III)
of complexes
spectrophotometrically kinetically
peroxide
as the rate of oxidation
two cations
although
of hydrogen
arrangement
to that for
from the strong
Mn3+HO~
aq
mn3+H02
aq + H20
3 t2g e g
of mn(lll)
to
-1
10
THE REACTION OF Ag(ll)
the t23eg g 2 arrangement
attain
polarizability gen atom
the cation that
this
fication 3+ Feag
for
(g) and complex
the high is also
of the charge
peroxy
these
complexes
confirm
that
and
not H202
which
(8),
as OH-
value
inner
sphere. spectrum
are
inner
sphere.
similar
K is not
related
to the overall
the
t2g3eg2
Evidence
for
this
of Co 3+ aq
with
hydrogen
475 m/~ Plots
independent of acidity
of the in the
oxidation
inner-sphere
order
rate
range
by ~]n(III)
ratio
1.5-3.7 (1)
transfer
values
of K
3 x lOg&.
tendency
3+ " ,
oF the to form
in ~In3+H02
the
HO 2
H20 molecule.
power
Cr aq 3+ and
aq
the
low heat
Fe aq ~+
reaction
(8).
It
of h y d r o g e n
(E ° = 2°Ov)(lO)
(ll). (prepare,l media
stopped-flow
constant
of
Co3+> Mn3+>Fe
potential
of AO(II)
) against
initial
electron
V aq' 3+
in p e r c h l o r a t e
(O.D.-O.D&~
first
with
at 25°C
a Durrum-Gibson
replaced
for F~n~*OH"aq from
has a redox
reaction
peroxide
using
of log
observed
the
rapid
modi-
that
polarizable
extra
to i n v e s t i g a t e
([ ° = 1.gSv)
(2) and
suggestion
polarizing
covalency
found
therefore A gaq 2+ which
with
The
through
is also
the
of m n+ varies
is some
3. compared of Mnaq
is of interest,
~that
there
arrangement
of hydrolysis
peroxide
i.e.
with
suggests
The high
to the
potential
in solution
is c o n t i g u o u s
is the highly
as the redox
cation
the oxy-
¢.mole -I for Mn3+H02 -) at
However,
only
with
~.mo]B -I for Co3+H02-(2),
ligsnd
is very
the higher
compared
of Co 3+ aq
supports
~ 5 x I016
the
and
The c o n s i d e r a b l e
HO 2
(6 x 1013
Vol. 5, No. 1
of K for BIn3+H02
with
mole -I for Fe3+H02-(4), 25°C
atom
transfer
complexes
overlap
oxygen
molecule
(4) on c o m p l e x i n g
these
by sp3-d
of the anionic
in the water
WITH HYDROGEN PEROXIDE
time
has
electrolytically) been
followed
spectrophotometer.
are always
at constant
linear
ionic
and
strength
l A g ( I f ) ] / [ H 2 0 2 ] , or [Ag(1)] ~ HCIO 4.
: the rate 4, and
at
This
is analogous
determining
Ag 2 + HO 2
the is and to
step
is the
~nust have
a high
Vol. 5, No. |
THE REACTION OF Ag(ll) WITH HYDROGEN PEROXIDE
formation order
equilibrium
kinetics
to
constant
be
Ag2+H02 Ag suqgests due to
with
Ag(II)]
foltot~fed
by
5
m n+
the
sec
strong
+ HO 2
varying
(8)
3ahn-Teller smooth
out
stabilizations
ligands
with
the
in
H
~3+ ao'
H20.
therefore ionic
M m+ is
+ OH -
increased
are
likely
:
ligand
rL1n+
r~n+
to be
with
same
o×ygen
and
25°C.
the
suggests
(1). d 4 to
two
from
a
Effect
;
half-filled
The
covalency
from
(13).
of
preferential
from
Effect
Crystal , H20
the
field
and
HO 2
(8,13). References
i.
C.F.
W e l l s and D. flays, I n o r q . N u c l . C h e m . L e t t e r s , (lq68) ; ] . C h e m . Soc., A, 665 (lg68).
2.
O.H.
~ a × e n d a l e and C.F. 53, 800 (ig57).
3.
W.G.
Barb, 3°H. B a x e n d a l e , P. G e o r g e and Trans.Faraday 5oc., 47, 591 (lgSl).
Wells,
Trans. Faraday
K.R.
the
+ OH - d i s t a n c e s
Jahn-Teller
OH
and
constancy
Mn+
where
the
d I0 and
Jahn-Teller
for
rapidly
Mn(III)
arising
a dynamic
the
4 is
÷ OH 2 ) d i s t a n c e
distances
Ag(II)
therefore
found
(12). F e3+ aq
of
= 4.0
and
of
Ag2+H02 -
anionic
reaction
complexes
the
, this
stoichiometry
covalency
and
(or
in
d g to a t t a i n
stability
unlikely
mn++
same
as
+ anion
solution
of
strength
P~J zero,
that
rln ~ HO 2
exists
The
first
02
+
polarizability
3+ Craq
for
t 6 2geg3 a r r a n g e m e n t
throuqh
in
+
overlap
temperature,
extra
the
the
+
at
in m n+
suggests
Effect
Ag +
: increased
of
the
)
tendency-for
d sub-shell
in
-i
distance of
HO 2
in
activation
hydrolysis
shortening
may
of
+
the
and
to c h a n g e
influence
of
atom
with
Ag +
sp3-d
for
= 2,
: k = ii
very
filled
of
analogy
~
higher
oxygen
explanations
shorter
are
the
d 5 by c o v a l e n c y
possible
fully
degree
/&[H202]
This
heat
the
energy
attain
k
tendency
insensitive
overall
or
a high
t 26 g e g 4 and
compared
By
HO 2 •
strong
attain
k is
+
that
to the
~[
2+
-1)
(K ~ 5 × l O l 6 ~ . m o l e
observed.
11
~,
43
Soc.,
Hargrave,
as
THE REACTION OF Ag(ll) WITH HYDROGEN PEROXIDE
12
4 .
M.G.
Evans, P. George 230 (194g).
So
C.F.
Wells,
6.
P. Jones, R. Kitching, M.L. Tobe and W.F.K. Trans. Faraday Soc., 55, 79 (1959).
7.
C.F.
l!lells and G. Davies, ~ature, J.Cnem. Soc., A, 1858 (1967).
8o
C.F.
Wells,
9.
C.W.
lO.
A.A.
Noyes, D. DeVault, C.D. Coryell and T.J. O.Amer.Chem.5oc., 59, 1326 (1937)
ii.
D.A.
Johnson
12.
C.5.G. Phillips and R.i.P. Williams, "Inorganic Chemistry", Vol. 2 (Clarendon Press, Oxford, 1966), pp. 169-184.
13.
C.F. ~ells
Discussion
Nature,
and N. Uri,
Vol. 5, No. 1
Faraday
205,
693
lrans. Faraday
5oc., 29,
205,
Sharp,
and G. Oavies,
692
45,
(ig60). Wynne-Oones,
(1965);
(1965).
Davies, J.Chem. Soc., lgSl, 1256; (Butterworths, London, 1962) p.84.
and A.G.
171
Soc.,
"Ion Association"
J.Chem. Soc.,
J.Chem. Soc.,
3490
~858
Oeahl, (1964)
(i967).
NUCL.
CHEM.
LETTERS
vol.
5,
pp.
9-12,
1969.
THE mECHANI5~I OF THE REACTION HYDROGEN by Department
PEROXIDE C.F.
Pergemn~, Presl.
OF Ag(ll)
AN Ag2+H02
:
Wells
and
Printed
Greet
Brlta;n.
WITH
COMPLEX
D. Mays
of Chemistry,
University
of Birmingham,
P.O.
Birmingham
15,
Box 363,
In
Edgbaston,
England.
(Received 2 November 79~)
The rate of oxidation of the same order much
faster
latter
than that
by Co(III)
m n+ second
the presence
except
whether
possibly
with mn(III), order
tified
they
with
first
a very high
mn3+OH - (K ~
mn~
in
the oxidation
order
and
high
[H202]
(5),
(6).
However,
[H202],
:
the
to determine
of FMn(III)],
(1)
is
mn+H02 - is established
the rate determining inner-sphere
electron
the first
step is identransfer
l, with
equilibrium /~
via
2 and 3.
constant
The h i g h value
ions) :
is comparable both arise
H02 aq
for the electronic
1 for
the
for Mn3+H02 - ( K > 5 x lO 16 ~.mole
&.mole -1 ) (7) +
Mn 2+ + HO 2.
\ tendency
are observed,
is independent
the separated
1014
With
and
formation
from
(3).
are observed,
equilibrium
calculated
(1) but
kinetics
for mn3+H02
formation
by mn(III)
kinetics
at very
mn3+H02 ~ constant
Ag(II)
(4) it is not possible
Fe(III)
and acidity
as the first
order
participate
order
rate constant
!Mn(II)!
(2)
by
(2) and Fe(III)
of complexes
spectrophotometrically kinetically
peroxide
as the rate of oxidation
two cations
although
of hydrogen
arrangement
to that for
from the strong
Mn3+HO~
aq
mn3+H02
aq + H20
3 t2g e g
of mn(lll)
to
-1
10
THE REACTION OF Ag(ll)
the t23eg g 2 arrangement
attain
polarizability gen atom
the cation that
this
fication 3+ Feag
for
(g) and complex
the high is also
of the charge
peroxy
these
complexes
confirm
that
and
not H202
which
(8),
as OH-
value
inner
sphere. spectrum
are
inner
sphere.
similar
K is not
related
to the overall
the
t2g3eg2
Evidence
for
this
of Co 3+ aq
with
hydrogen
475 m/~ Plots
independent of acidity
of the in the
oxidation
inner-sphere
order
rate
range
by ~]n(III)
ratio
1.5-3.7 (1)
transfer
values
of K
3 x lOg&.
tendency
3+ " ,
oF the to form
in ~In3+H02
the
HO 2
H20 molecule.
power
Cr aq 3+ and
aq
the
low heat
Fe aq ~+
reaction
(8).
It
of h y d r o g e n
(E ° = 2°Ov)(lO)
(ll). (prepare,l media
stopped-flow
constant
of
Co3+> Mn3+>Fe
potential
of AO(II)
) against
initial
electron
V aq' 3+
in p e r c h l o r a t e
(O.D.-O.D&~
first
with
at 25°C
a Durrum-Gibson
replaced
for F~n~*OH"aq from
has a redox
reaction
peroxide
using
of log
observed
the
rapid
modi-
that
polarizable
extra
to i n v e s t i g a t e
([ ° = 1.gSv)
(2) and
suggestion
polarizing
covalency
found
therefore A gaq 2+ which
with
The
through
is also
the
of m n+ varies
is some
3. compared of Mnaq
is of interest,
~that
there
arrangement
of hydrolysis
peroxide
i.e.
with
suggests
The high
to the
potential
in solution
is c o n t i g u o u s
is the highly
as the redox
cation
the oxy-
¢.mole -I for Mn3+H02 -) at
However,
only
with
~.mo]B -I for Co3+H02-(2),
ligsnd
is very
the higher
compared
of Co 3+ aq
supports
~ 5 x I016
the
and
The c o n s i d e r a b l e
HO 2
(6 x 1013
Vol. 5, No. 1
of K for BIn3+H02
with
mole -I for Fe3+H02-(4), 25°C
atom
transfer
complexes
overlap
oxygen
molecule
(4) on c o m p l e x i n g
these
by sp3-d
of the anionic
in the water
WITH HYDROGEN PEROXIDE
time
has
electrolytically) been
followed
spectrophotometer.
are always
at constant
linear
ionic
and
strength
l A g ( I f ) ] / [ H 2 0 2 ] , or [Ag(1)] ~ HCIO 4.
: the rate 4, and
at
This
is analogous
determining
Ag 2 + HO 2
the is and to
step
is the
~nust have
a high
Vol. 5, No. |
THE REACTION OF Ag(ll) WITH HYDROGEN PEROXIDE
formation order
equilibrium
kinetics
to
constant
be
Ag2+H02 Ag suqgests due to
with
Ag(II)]
foltot~fed
by
5
m n+
the
sec
strong
+ HO 2
varying
(8)
3ahn-Teller smooth
out
stabilizations
ligands
with
the
in
H
~3+ ao'
H20.
therefore ionic
M m+ is
+ OH -
increased
are
likely
:
ligand
rL1n+
r~n+
to be
with
same
o×ygen
and
25°C.
the
suggests
(1). d 4 to
two
from
a
Effect
;
half-filled
The
covalency
from
(13).
of
preferential
from
Effect
Crystal , H20
the
field
and
HO 2
(8,13). References
i.
C.F.
W e l l s and D. flays, I n o r q . N u c l . C h e m . L e t t e r s , (lq68) ; ] . C h e m . Soc., A, 665 (lg68).
2.
O.H.
~ a × e n d a l e and C.F. 53, 800 (ig57).
3.
W.G.
Barb, 3°H. B a x e n d a l e , P. G e o r g e and Trans.Faraday 5oc., 47, 591 (lgSl).
Wells,
Trans. Faraday
K.R.
the
+ OH - d i s t a n c e s
Jahn-Teller
OH
and
constancy
Mn+
where
the
d I0 and
Jahn-Teller
for
rapidly
Mn(III)
arising
a dynamic
the
4 is
÷ OH 2 ) d i s t a n c e
distances
Ag(II)
therefore
found
(12). F e3+ aq
of
= 4.0
and
of
Ag2+H02 -
anionic
reaction
complexes
the
, this
stoichiometry
covalency
and
(or
in
d g to a t t a i n
stability
unlikely
mn++
same
as
+ anion
solution
of
strength
P~J zero,
that
rln ~ HO 2
exists
The
first
02
+
polarizability
3+ Craq
for
t 6 2geg3 a r r a n g e m e n t
throuqh
in
+
overlap
temperature,
extra
the
the
+
at
in m n+
suggests
Effect
Ag +
: increased
of
the
)
tendency-for
d sub-shell
in
-i
distance of
HO 2
in
activation
hydrolysis
shortening
may
of
+
the
and
to c h a n g e
influence
of
atom
with
Ag +
sp3-d
for
= 2,
: k = ii
very
filled
of
analogy
~
higher
oxygen
explanations
shorter
are
the
d 5 by c o v a l e n c y
possible
fully
degree
/&[H202]
This
heat
the
energy
attain
k
tendency
insensitive
overall
or
a high
t 26 g e g 4 and
compared
By
HO 2 •
strong
attain
k is
+
that
to the
~[
2+
-1)
(K ~ 5 × l O l 6 ~ . m o l e
observed.
11
~,
43
Soc.,
Hargrave,
as
THE REACTION OF Ag(ll) WITH HYDROGEN PEROXIDE
12
4 .
M.G.
Evans, P. George 230 (194g).
So
C.F.
Wells,
6.
P. Jones, R. Kitching, M.L. Tobe and W.F.K. Trans. Faraday Soc., 55, 79 (1959).
7.
C.F.
l!lells and G. Davies, ~ature, J.Cnem. Soc., A, 1858 (1967).
8o
C.F.
Wells,
9.
C.W.
lO.
A.A.
Noyes, D. DeVault, C.D. Coryell and T.J. O.Amer.Chem.5oc., 59, 1326 (1937)
ii.
D.A.
Johnson
12.
C.5.G. Phillips and R.i.P. Williams, "Inorganic Chemistry", Vol. 2 (Clarendon Press, Oxford, 1966), pp. 169-184.
13.
C.F. ~ells
Discussion
Nature,
and N. Uri,
Vol. 5, No. 1
Faraday
205,
693
lrans. Faraday
5oc., 29,
205,
Sharp,
and G. Oavies,
692
45,
(ig60). Wynne-Oones,
(1965);
(1965).
Davies, J.Chem. Soc., lgSl, 1256; (Butterworths, London, 1962) p.84.
and A.G.
171
Soc.,
"Ion Association"
J.Chem. Soc.,
J.Chem. Soc.,
3490
~858
Oeahl, (1964)
(i967).