Chlorine dioxide reduction by aqueous iron(II) through outer-sphere and inner-sphere electron-transfer pathways

Article abstract of DOI:10.1021/ic048809q

The reduction of ClO₂ to ClO₂^- by aqueous iron(II) in 0.5 M HClO₄ proceeds by both outer-sphere (86%) and inner-sphere (14%) electron-transfer pathways. The second-order rate constant for the outer-sphere reacti

Full text of DOI:10.1021/ic048809q

Inorg. Chem. 2004, 43, 7545−7551
Chlorine Dioxide Reduction by Aqueous Iron(II) through Outer-Sphere
and Inner-Sphere Electron-Transfer Pathways
Lu Wang, Ihab N. Odeh, and Dale W. Margerum*
Department of Chemistry, Purdue UniVersity, West Lafayette, Indiana 47907
Received August 27, 2004
-
The reduction of ClO₂ to ClO₂ by aqueous iron(II) in 0.5 M HClO₄ proceeds by both outer-sphere (86%) and
inner-sphere (14%) electron-transfer pathways. The second-order rate constant for the outer-sphere reaction is 1.3
2
×
10⁶ M^-1 s^-1. The inner-sphere electron-transfer reaction takes place via the formation of FeClO₂ ⁺ that is observed
as an intermediate. The rate constant for the inner-sphere path (2.0
of a coordinated water to give an inner-sphere complex between ClO₂ and Fe(II) that very rapidly transfers an
×
10⁵ M^-1 s^-1) is controlled by ClO₂ substitution
2+
+
electron to give (Fe^III(ClO₂^-)(H₂O)₅ )_IS. The composite activation parameters for the ClO₂/Fe(aq)² reaction (inner-
1
1
2+
sphere
+
outer-sphere) are the following:
∆
H_r^q
)
40 kJ mol^-
-
;
∆
S_r^q
)
1.7 J mol^- K^-1. The Fe^IIIClO₂ inner-
sphere complex dissociates to give Fe(aq)³ and ClO₂ (39.3 s^-1). The activation parameters for the dissociation
+
q
1
q
1
+
of this complex are the following:
∆H_d ) ; ∆S_d )
76 kJ mol^- 32 J K^- mol^-1. The reaction of Fe(aq)² with
-
1
1
) 2.0 ×
10³ M^- s^- that is five
-
ClO₂ is first order in each species with a second-order rate constant of k_ClO
2
times larger than the rate constant for the Fe(aq)² reaction with HClO₂ in H₂SO₄ medium ([H⁺]
)
0.01
−
0.13 M).
+
The composite activation parameters for the Fe(aq)²⁺/Cl(III) reaction in H₂SO₄ are
∆
H_Cl(III)
)
41 kJ mol^- and
q
1
q
1
1
∆
S_Cl(III)
)
48 J mol^- K^-
.
-
Introduction
yields ClO₃ and Cl^- in acidic solutions with exposure to
sunlight.^12-15
Chlorine dioxide has been used as an alternative disinfec-
tant because chlorination sometimes leads to the formation
of carcinogens such as trihalomethanes (THM) as well as
other hazardous byproducts.¹ Chlorine dioxide is a powerful
oxidant and does not form THM.² The disadvantage of its
use in water treatment is the potential production of other
undesirable disinfection byproducts such as chlorite and
Little information is available about the kinetics and
mechanism of the reaction between Fe²⁺ and ClO₂. Knocke
and co-workers¹⁶ reported a five-electron reduction of ClO₂
for the stoichiometry of the Fe²⁺ reaction with ClO₂ (eq 1),
but they did not give a rate expression or provide sufficient
information to deduce the reaction pathways. The objective
of this work is to investigate the kinetics and mechanism of
ClO₂ reduction by Fe(aq)²⁺. To better understand the ClO₂/
Fe(aq)²⁺ reaction, the kinetics of the subsequent Fe(aq)²⁺/
Cl(III) reaction are also studied.
-
chlorate ions.^3,4 The disproportionation of ClO₂ forms ClO₂
-
and ClO₃ in alkaline solutions,^5-11 and its decomposition
* Author to whom correspondence should be addressed. E-mail:
margerum@purdue.com.
4H⁺ + ClO₂ + 5Fe²⁺ f Cl^- + 5Fe³⁺ + 2H₂O (1)
(1) Rook, J. J. J. Water Treat. Exam. 1974, 23, 234-243.
(2) Lykins, B. W.; Griese, M. H. J. Am. Water Works Assoc. 1986, 78,
88-93.
Experimental Section
Reagents. The method of synthesis and standardization of
chlorine dioxide stock solution was described previously.¹⁷ Solutions
(3) Werdehoff, K. S.; Singer, P. C. J. Am. Water Works Assoc. 1987, 79,
107-113.
(4) Gordon, G.; Slootmaekers, B.; Tachiyashiki, S.; Wood; D. W. J. Am.
Water Works Assoc. 1990, 82, 160-165.
(5) Bray, W. C. Z. Anorg. Allg. Chem. 1906, 48, 217-250.
(6) Halperin, J.; Taube, H. J. Am. Chem. Soc. 1952, 74, 375-380.
(7) Granstrom, M. L.; Lee, G. F. Public Works 1957, 88, 90-92.
(8) Gordon, G.; Keiffer, R. G.; Rosenblatt, D. H. In Progress in Inorganic
Chemistry; Lippard, S. J., Ed.; Wiley-Interscience: New York, 1972;
pp 201-287.
(12) Basco, N.; Dogra, S. K. Proc. R. Soc. London, Ser. A 1971, 323,
29-68.
(13) Bowen E. J.; Cheung, W. M. J. Chem. Soc. 1932, 159, 1200-1207.
(14) Vel Leitner, N. K.; De Laat, J.; Dore, M. Water Res. 1992, 26, 1655-
1664; 1992, 26, 1665-1672.
(15) Zika, R. G.; Moore, C. A.; Gidel, L. T.; Cooper, W. J. In Water
Chlorination Chemistry, EnVironmental Impact and Health Effect;
Lewis: Chelsea, MI, 1985; Vol. 5, pp 1041-1053.
(9) Emerich, D. E. Ph.D. Dissertation, Miami University, 1981.
(10) Gordon, G. Pure Appl. Chem. 1989, 61, 873-878.
(11) Odeh, I. N.; Francisco, J. S.; Margerum, D. W. Inorg. Chem. 2002,
41, 6500-6506.
(16) Knocke, W. R.; Van Benschoten, J. E.; Kearney, M. J.; Soborski, A.
W.; Reckhow, D. A. J. Am. Water Works Assoc. 1991, 83, 80-87.
10.1021/ic048809q CCC: $27.50
Published on Web 10/16/2004
© 2004 American Chemical Society
Inorganic Chemistry, Vol. 43, No. 23, 2004 7545

Wang et al.
of ClO₂ were protected from light and stored at 5 °C. The ClO₂
stock solution was standardized spectrophotometrically on the basis
of the molar absorptivity of ClO₂, ꢀ ) 1230 M^-1 cm^-1 at 359 nm.¹⁷
Sodium chlorite was purified and recrystallized as described
previously,¹⁸ and stock solutions were standardized spectrophoto-
metrically (ꢀ ) 154 M^-1 cm^-1 at 260 nm).¹⁷ Perchloric acid stock
solution was prepared by dilution of Ar-sparged concentrated acid,
and standardized by titration with standardized NaOH. The stock
solution of Fe(II) perchlorate was prepared by dissolving reagent
grade iron wire in 1 M HClO₄ with gentle heating to increase the
rate of dissolution. The Fe²⁺ concentrations of the stock solutions
were determined by titration with standardized KMnO₄. The KMnO₄
solution was standardized by the primary reagent arsenic oxide.
The stock Fe²⁺ solutions for the study in H₂SO₄ medium were
prepared by dissolving Fe(NH₄)₂(SO₄)₂‚6H₂O in sulfuric acid. To
avoid the oxidation of Fe²⁺ by oxygen dissolved in water, all Fe²⁺
solutions were made with Ar-sparged deionized, distilled water.
Kinetic Measurements. The kinetics and reaction spectra were
obtained by an Applied PhotoPhysics SX 18 MV stopped-flow
spectrophotometer (APPSF, optical path length ) 0.962 cm). All
reactions were run under pseudo-first-order conditions with Fe(aq)²⁺
in large excess over [ClO₂] and [Cl(III)]_T. Measured rate constants
were corrected for mixing by accounting for the mixing rate
constant.¹⁹ Because Fe(III) readily hydrolyzes, the study was
conducted in 0.50 M HClO₄ solution (unless otherwise specified)
to prevent hydrolysis and precipitation of hydroxide species.
SigmaPlot 8.0²⁰ was used for regression analysis.
Figure 1. First-order fit kinetic traces for the decay of FeClO₂²⁺: (a) λ
) 359 nm; (b) λ ) 500 nm. Conditions: [Fe²⁺] ) 3.69 × 10^-4 M; [ClO₂]_i
) 2.2 × 10^-5 M; [HClO₄] ) 0.50 M; 25.0 °C. The cell path length is
0.962 cm.
Table 1. Lack of [Fe²⁺] Dependence for the Observed Rate Constants
in Studies of the ClO₂/Fe²⁺ Reaction at 359 nm in HClO₄
a,b
Results and Discussion
[Fe²⁺] (mM)
k_obsd (s^-1
)
[Fe²⁺] (mM)
k_obsd (s^-1
)
2+
FeClO₂ Formation. Chlorine dioxide has a strong
2.36
1.97
1.57
40.0
39.5
38.8
1.18
0.98
0.36
38.7
38.8
40.5
absorption band at 359 nm while Fe(aq)²⁺ and Fe(aq)³⁺ do
not absorb significantly.²¹ Nevertheless, when ClO₂ is mixed
with excess Fe(aq)²⁺, a first-order decay is observed at this
wavelength (Figure 1a) with an average k_obsd value of 39.3(8)
s^-1 that is independent of the Fe(aq)²⁺ concentration (Table
1). We propose that an intermediate forms rapidly and the
observed absorbance decrease is due to its loss rather than
the loss of ClO₂. To ascertain the existence of the intermedi-
ate, kinetic spectra are taken on the APPSF over reaction
times of 20 ms (Figure 2a) and 100 ms (Figure 2b). The
resulting spectra have absorbance bands from 250 to 500
nm. The absorbance in Figure 2a,b extends to higher
wavelength range (>450 nm), where none of the known
^a Conditions: [ClO₂]_i ) 9.1 × 10^-5 M, [HClO₄] ) 0.50 M, 25.0 °C.
^b Average k_obsd ) 39.3(8) s^-1
.
(Figure 1a) and 500 nm (Figure 1b) indicates that the decay
observed at both wavelengths can be attributed to the same
2+
intermediate species. A FeClO₂ complex is the proposed
intermediate formed as one of the products of the ClO₂/
2+
Fe(aq)²⁺ redox reaction (eq 2). The term FeClO₂ is used
to represent the inner-sphere complex (Fe^III(ClO₂^-)(H₂O)₅²⁺)_IS.
2+
Fe(aq)²⁺ + ClO₂ f FeClO₂
K_i
(2)
-
components (Fe(aq)³⁺, Fe(aq)²⁺, ClO₂, or ClO₂ ) in this
2+
The formation of an FeClO₂ complex in the Fe(III)-
chlorite ion system has been reported by Fa´bia´n and Gor-
don.²² They assigned the absorbance between 470 and 540
nm to FeClO₂²⁺ which is consistent with our results. These
authors estimated a first-order rate constant for the dissocia-
tion of FeClO₂²⁺ into Fe(aq)³⁺ and ClO₂ to be 19.5 s^-1 at 25.0
°C and µ ) 1.0 M (NaClO₄). Their observation supports
system have significant absorbance. The kinetic trace taken
at 500 nm (shown in Figure 3) provides evidence for the
formation and decay of a new species. When Fe(aq)²⁺ (0.369
mM postmixing) is mixed rapidly with ClO₂ (0.022 mM
postmixing), the trace shows a fast growth in absorbance
that is complete in 10 ms and is followed by a decay during
the next 100 ms. The decay is first-order, and the measured
rate constant is 39.3 s^-1. This is consistent with the first-
order rate constant obtained at 359 nm (Table 1). The
agreement between the first-order rate constants at 359 nm
2+
our assignment of FeClO₂ as the intermediate species.
Kinetics of the ClO₂/Fe(aq)²⁺ Redox Reaction. The
equilibrium constant for the reaction in eq 2 was reported
as K_i ) 5.0 × 10⁴ M^-1.²² The large value of K_i and our
kinetic trace in Figure 3 indicate that the oxidation of
(17) Furman, C. S.; Margerum, D. W. Inorg. Chem. 1998, 37, 4321-4327.
(18) Wang, L.; Nicoson, J. S.; Huff Hartz, K. E.; Francosco, J. S.; Margerum
D. W. Inorg. Chem. 2002, 41, 108-113.
(19) Dickson, P. N.; Margerum, D. W. Anal. Chem. 1986, 58, 3153-3158.
(20) SigmaPlot 8.0 for Windows; SPPS Inc.: Chicago, IL, 2002.
(21) Whiteker, R. A.; Davidson, N. J. Am. Chem. Soc. 1953, 75,
3081-3085.
2+
Fe(aq)²⁺ by ClO₂ to form FeClO₂ is very favorable and
rapid. Therefore, in the presence of a large excess Fe(aq)²⁺,
(22) Fa´bia´n, I.; Gordon, G. Inorg. Chem. 1991, 30, 3994-3999; 1992, 31,
2144-2150.
7546 Inorganic Chemistry, Vol. 43, No. 23, 2004

Chlorine Dioxide Reduction by Aqueous Iron(II)
2+
Figure 4. First-order fit of the kinetic trace for the formation of FeClO₂
.
Conditions: [Fe²⁺] ) 3.69 × 10^-4 M; [ClO₂]_i ) 2.2 × 10^-5 M; [HClO₄]
) 0.50 M; 25.0 °C; λ ) 500 nm. The cell path length is 0.962 cm. What
is shown here is a single run.
Figure 2. Kinetic spectra for the reaction of Fe²⁺ with ClO₂ in 0.50 M
HClO₄. (a) The time interval between first scan and the last scan is 20 ms,
and the time interval between scans is 0.4 ms. (b) The time interval between
the first scan and the last scan is 100 ms, and the time interval between
scans is 5 ms. Conditions: [ClO₂] ) 1.82 × 10^-4 M; [Fe²⁺] ) 1.97 ×
10^-3 M. The cell path length is 0.962 cm.
Figure 5. [Fe²⁺] dependence of the observed rate constant for the oxidation
of Fe²⁺ by ClO₂. Conditions: [ClO₂]_i ) 2.2 × 10^-5 M; [HClO₄] ) 0.50
M; 25.0 °C; λ ) 500 nm; slope ) 1.5(1) × 10⁶ M^-1 s^-1; intercept ) -3(19)
s^-1. Rate constants represent an average of at least five measurements at
each [Fe²⁺], and standard deviations are shown. All the shown rate constants
were corrected for mixing.
Figure 3. Kinetic profile of the Fe²⁺/ClO₂ reaction. Conditions: [Fe²⁺
]
) 3.69 × 10^-4 M; [ClO₂]_i ) 2.2 × 10^-5 M; [HClO₄] ) 0.50 M; 25.0 °C;
λ ) 500 nm. The cell path length is 0.962 cm.
Figure 6. Kinetic profile of the Fe²⁺/ClO₂ reaction at 260 nm: (a)
2+
2+
formation of [Fe(ClO₂^-)(H₂O)₅ ]_IS; (b) decay of [Fe(ClO₂^-)(H₂O)₅ ]_IS;
(c) Fe(aq)³⁺ formation from Cl(III) and Fe(aq)²⁺. Conditions: [Fe²⁺] )
3.92 × 10^-4 M; [ClO₂]_i ) 2.2 × 10^-5 M; [HClO₄] ) 0.50 M; 25.0 °C.
The cell path length is 0.962 cm.
2+
the consumption of ClO₂ to produce FeClO₂ is rapid. As
2+
a consequence, the decay of FeClO₂ no longer depends
on [Fe²⁺]. The spectra in Figure 2a,b show that FeClO₂
2+
has a significant absorbance at 359 nm, where the absorbance
loss of ClO₂ is compensated by the absorbance increase due
to the formation of FeClO₂²⁺. Since it is difficult to monitor
the reaction in eq 2 at 359 nm due to the absorbance of ClO₂,
the kinetics of FeClO₂²⁺ formation from the Fe²⁺/ClO₂ reac-
tion are investigated at 500 nm. At this wavelength the absor-
bance of ClO₂ is negligible. A first-order reaction is observed
at 500 nm (Figure 4), where the rate constant, k_obs1, depends
on [Fe²⁺] (Figure 5). The k_obs1 values have been corrected
for the mixing efficiency of the APPSF.^19,23 From the slope
of the plot in Figure 5, a second-order rate constant (k^2nd) of
1.5(1) × 10⁶ M^-1 s^-1 is obtained for the overall reaction.
Subsequent Reaction: Cl(III)/Fe(aq)²⁺. The term Cl(III)
is used in the current study to represent the summation of
-
HClO₂ and ClO₂ . The kinetic spectra in Figure 2b show a
growth in absorbance at 260 nm as FeClO₂²⁺ decomposes. A
kinetic trace at 260 nm taken over 500 ms (Figure 6) shows
rapid formation of FeClO₂²⁺ (Figure 6, region a) and its sub-
sequent decay in less than 100 ms (Figure 6, region b). An-
other species begins to form at ∼100 ms (Figure 6, region c).
The kinetic trace taken at a longer reaction time under the
same conditions shows a much larger absorbance increase at
260 nm within 10 s. These data fit a first-order rate constant
with a k_obs2 ) 0.39 s^-1 (Figure S1, Supporting Information).
The reaction of Fe(aq)²⁺ with Cl(III) in 2.0 M LiClO₄/HClO₄
has been reported.²⁴ The increase in absorbance in Figure 6,
region c, can be assigned to the Fe(aq)²⁺/Cl(III) reaction (eq
3).
(23) Nicoson, J. S.; Margerum, D. W. Inorg. Chem. 2002, 41, 342-347.
(24) Ondrus, M. G.; Gordon, G. Inorg. Chem. 1972, 11, 985-989.
4Fe(II) + Cl(III) f 4Fe(III) + Cl^-
(3)
Inorganic Chemistry, Vol. 43, No. 23, 2004 7547

Wang et al.
In our preliminary studies, H₂SO₄ was used to control the
pH of the Fe(aq)²⁺ reactions with ClO₂ and Cl(III). The
kinetics of these reactions were followed by monitoring
+
FeSO₄ formation at 303 nm (ꢀ₃₀₃ ) 1960 M^-1 cm^-1). The
dependence of both the Fe(aq)²⁺/ClO₂ and Fe(aq)²⁺/Cl(III)
reactions on [Fe(aq)²⁺] gave identical second-order rate
constants under the same experimental conditions. On the
basis of these studies, we conclude that the Fe(aq)²⁺/ClO₂
reaction must be fast and the observed kinetic traces represent
the subsequent Fe(aq)²⁺/Cl(III) reaction. We determined the
[H⁺] dependence of the Fe(aq)²⁺/Cl(III) in H₂SO₄ medium
Figure 7. Dependence of the rate of Fe²⁺/Cl(III) reaction on the acid
concentration in H₂SO₄ medium. Conditions: [Fe²⁺] ) 0.15 mM; [Cl(III)]
) 5 µM; 303 nm; 25.0 °C; k_HClO ) 3.5 × 10² M^-1 s^-1; k_ClO ) 2.0 × 10
3
-
2
2
-
and found that both ClO₂ and HClO₂ react with Fe(aq)²⁺.
M^-1 s^-1. The ionic strength at each point was controlled by the excess
H₂SO₄.
-
2-
The pH was controlled by a HSO₄ /SO₄ buffer, where
-
pK_a^HSO ) 1.32 at 25.0 °C and µ ) 0.5 M.²⁵ Ondrus and
4
Gordon²⁴ reported that Fe(II) reacts with Cl(III) through two
-
pathways, one with ClO₂ and another with HClO₂, eq 4.
We examined the same system as a part of the overall ClO₂/
Fe(aq)²⁺ study. Our data (Figure 7) show that the reaction
-
of Fe²⁺ with ClO₂ (k_ClO ) 2.0 × 10³ M^-1 s^-1), eq 5a, is
-
2
five times faster than the Fe²⁺/HClO₂ reaction (k_HClO ) 3.5
2
× 10² M^-1 s^-1), eq 5b, where pK_a^HClO ) 1.95 at 25.0 °C
2
and µ ) 0.5 M.²⁶ The species Cl(II) is reduced rapidly by
another Fe(aq)²⁺, eq 6, to give Cl(I) (HOCl or OCl^-). HOCl
reacts further with two Fe(aq)²⁺ to give two Fe(aq)³⁺ and
Cl^-, eq 7. The findings in the literature and our preliminary
results indicate that k_HOCl is ∼3.5 × 10³ M^-1 s^-1 and is
independent of the acid concentration.^27,28 Equations 8a,b are
the rate expressions for the oxidation of Fe(aq)²⁺ by Cl(III).
The solid line in Figure 7 is a fit of the data to eq 8b.
Figure 8. First-order dependence in [Fe²⁺] of the Cl(III)/Fe(aq)²⁺ reaction.
Conditions: [Cl(III)]_T ) 0.39 mM; 25.0 °C; µ ) 1.0 M; [HClO₄] ) 0.10
M; λ ) 260 nm; slope ) 1.77(2) × 10³ M^-1 s^-1; intercept ) 0.2(2) s^-1
.
smaller than the Fe²⁺/ClO₂ electron-transfer rate constant.
+
³⁺/SO₄
Fe(aq)³⁺ + SO₄^2- f FeSO₄
Fe(aq)³⁺ + HSO₄^- f FeSO₄⁺ + H⁺
k^Fe
(9)
HClO₂ a ClO₂^- + H⁺
K_a^HClO
(4)
2
³⁺/HSO₄
k^Fe
(10)
Fe(aq)²⁺ + ClO₂^- f Fe(aq)³⁺ + Cl(II)
k_ClO (5a)
-
We observe the kinetics of the Fe²⁺/Cl(III) reaction in 0.11
M HClO₄ medium by following the first-order formation of
Fe(aq)³⁺ at 260 nm. The reaction has a first-order dependence
in [Fe²⁺] (Figure 8) with a second-order rate constant of 1.77
× 10³ M^-1 s^-1. This rate constant is in agreement with the
value predicted in the H₂SO₄ medium on the basis of the
acid-dependence study (1.9 × 10³ M^-1 s^-1 at [H⁺] ) 0.11
M) shown in Figure 7. This indicates that Fe²⁺/Cl(III)
reaction is not dependent on HSO₄^- and therefore data from
the H₂SO₄ medium can be used to predict the rate constant
for Fe²⁺/Cl(III) reaction in the HClO₄ medium.
2
Fe(aq)²⁺ + HClO₂ f Fe(aq)³⁺ + Cl(II) + H⁺
k_HClO
2
(5b)
rapid (6)
k_HOCl (7)
Fe(aq)²⁺ + Cl(II) f Fe(aq)³⁺ + Cl(I)
2Fe(aq)²⁺ + Cl(I) f 2Fe(aq)³⁺ + Cl^-
d[FeIII]
) k^Cl(III)[Fe(aq)²⁺][Cl(III)]
(8a)
dt
On the basis of the close values for k^Cl(III) and k_HOCl, we
expected complex kinetics for the Cl(III)/Fe(aq)²⁺ system.
Our findings included simple first-order dependence in [Cl-
(III)], a dependence in [H⁺] that follows eq 8b, and a
stoichiometry of 4 for Cl(III):Fe(aq)³⁺ as will be discussed
later in this section. The dependence on [H⁺] in Figure 7
would not have been observed if HOCl/Fe(aq)²⁺ was the
studied reaction. Sutin and co-workers, along with our
2
k
[H⁺] + k
[H⁺] + K_a^HClO
K_a^HClO
ClO_2-
HClO₂
d[FeIII]
) 4
[Fe²⁺][Cl(III)]
(8b)
(
)
2
dt
The [Fe^IIISO₄]⁺ absorption band at 303 nm can be used
to monitor the Fe(II) reaction with Cl(III), eqs 9 and 10.
However, it is not helpful in studies of Fe(II) reaction with
ClO₂ because the rate constants for the inner-sphere com-
³⁺/SO₄
plexation between Fe³⁺ and SO₄^2-/HSO₄^- (k^Fe
) (3.5-
(27) Conocchioli, T. J.; Hamilton, E. J.; Sutin, N. J. Am. Chem. Soc. 1965,
87, 926-927.
3+
/
HSO₄
4.6) × 10³ M^-1 s^-1 and k^Fe
) 51 M^-1 s^-1)^29,30 are
(28) Our preliminary data show k_HOCl ) 3.84(1) × 10³ M^-1 s^-1 in 0.045
M H₂SO₄ and 3.66(3) × 10³ M^-1 s^-1 in 0.50 M HClO₄.
(29) Margerum, D. W.; Cayley, G. R.; Weatherburn, D. C.; Pagenkopf, G.
K. In Coordination Chemistry; Martell A. E., Ed.; American Chemical
Society: Washington, DC, 1978; Vol. 2, p 16.
(25) Smith, R. M.; Martell, A. E. Critical Stability Constants. Volume 4:
Inorganic Complexes; Plenum Press: New York, 1979; p 79.
(26) Smith, R. M.; Martell, A. E. Critical Stability Constants. Volume 4:
Inorganic Complexes; Plenum Press: New York, 1979; p 134.
(30) Cavasino, F. P. J. Phys. Chem. 1968, 72, 1378-1384.
7548 Inorganic Chemistry, Vol. 43, No. 23, 2004

Chlorine Dioxide Reduction by Aqueous Iron(II)
preliminary data, indicate that HOCl/Fe(aq)²⁺ lacks depen-
dence in acid concentration.^27,28 The experimental data
enabled us to assign the observed rate constants to the Cl-
(III)/Fe(aq)²⁺ rather than the HOCl/Fe(aq)²⁺ system.
Table 2. Evidence for Outer-Sphere and Inner-Sphere
a
Electron-Transfer Reactions of Fe(aq)²⁺ with ClO₂
2+
10⁴[ClO₂]_i
(M)
10⁴[FeClO₂
(M)^b
]
% inner
sphere^e
IS
c
d
A_calc
A_meas
2.05
2.56
1.84
2.22
0.113
0.136
0.013
0.016
14
14
-
Figure 6 shows the rapid formation of a [Fe^III(ClO₂ )]²⁺
inner-sphere complex, region a, followed by its aquation to
give Fe(aq)³⁺ and Cl(III), region b. We attribute the increase
in absorbance in region c of Figure 6 to the Fe(aq)²⁺ reaction
with Cl(III). The second-order rate constant for the observed
reaction in this region is k_obs2/[Fe²⁺]′ ) 1.1 × 10³ M^-1 s^-1
at 0.50 M HClO₄, where [Fe²⁺]′ is the Fe²⁺ concentration
after all the ClO₂ has reacted. This value agrees within 27%
of the second-order rate constant for the Fe²⁺/Cl(III) reaction
determined on the basis of eq 8a (1.5 × 10³ M^-1 s^-1). The
agreement suggests that the increase in absorbance at 260
nm with the first-order rate constant of k_obs2 is due to the
Fe(aq)³⁺ generated from the Fe²⁺/Cl(III) reaction. The results
^a Conditions: [Fe²⁺] ) 3.58 × 10^-4 M, [HClO₄] ) 0.50 M, 25.0 °C.
^b [FeClO₂²⁺] is calculated from K_i ) 5.0 × 10⁴ M^{-1 22}
,
[ClO₂]_i, and [Fe²⁺].
^c A_cal is calculated from the ꢀ₅₁₀ ) 636 ( 10 M^-1 cm^{-1 22} and the [FeClO₂
]
2+
d
assuming 100% inner-sphere electron transfer. A_meas is measured for the
reaction of Fe(II) and ClO₂ at 510 nm. ^e 100A_meas/A_calc after A_meas was
corrected to account for the overlap between FeClO₂²⁺ formation and decay
as shown in eqs 11 and 12. The k_i and k_d values are 1.8 × 10⁵ M^-1 s^-1
(based on 12%) and 39.3 s^-1, respectively.
Scheme 1. Mechanism for Chlorine Dioxide Reduction by Fe(aq)²⁺
via Outer-Sphere and Inner-Sphere Pathways and Fe(aq)³⁺
Complexation with Chlorite Ion
-
support the proposal that ClO₂ is the initial product of the
2+
decay of FeClO₂
.
3+
The molar absorptivity of Fe(aq)³⁺, ꢀ^Fe ) 2.4(1) × 10³
M^-1 cm^-1, at 260 nm is measured in this study (Figure S2).
3+
With the value of ꢀ^Fe and the absorbance change ∆A
()0.221) in the reaction of Cl(III) with Fe(aq)²⁺, the
concentration of Fe(aq)³⁺ generated is calculated to be 0.095-
(5) mM. Accordingly, the ratio of [Fe(aq)³⁺] formed to [Cl-
(III)] lost is 4.3(2), where [Cl(III)] equals the initial ClO₂
concentration (0.022 mM). This [Fe(aq)³⁺]/[Cl(III)] ratio is
close to the expected value of 4.0 (eq 3).
transfer pathways. However, electron transfer via an outer-
sphere reaction is also possible.
The reported molar absorptivity for FeClO₂ is ꢀ₅₁₀
2+
)
Mechanism. The reaction of ClO₂ with Fe(aq)²⁺ to give
ClO₂^- and Fe(aq)³⁺ is thermodynamically very favorable (K
) 3700, where K is the equilibrium constant for the oxidation
636(10) M^-1 cm^-1.²² By use of this molar absorptivity, we
can determine whether ClO₂ reacts only by inner-sphere
electron transfer or if it reacts by a mixture of inner-sphere
and outer-sphere paths. To enhance the signal at 510 nm,
higher [ClO₂] (0.205 and 0.256 mM) are used to react with
a slight excess Fe²⁺ (0.358 mM) so that the reaction is not
too fast to measure on the APPSF. Due to the deadtime of
the stopped-flow instrument (∼2.5 ms), extrapolation to zero
time after correcting for mixing was needed. Table 2
summarizes the results. The A_meas is the maximum absorbance
of FeClO₂²⁺ measured at 510 nm for five kinetic traces. A_calc
is the value of absorbance calculated from ꢀ ) 636 M^-1 cm^-1
and [FeClO₂²⁺] (where [FeClO₂²⁺] is the equilibrium con-
centration calculated from K_i ) 5.0 × 10⁴ M^-1,²² [ClO₂]_i,
and [Fe²⁺]). A comparison of A_meas and A_calc values indicates
that only 12% of [ClO₂]_i reacts with Fe(aq)²⁺ via an inner-
sphere path. The other 88% of [ClO₂]_i must react by an outer-
sphere path.
-
of Fe(aq)²⁺ by ClO₂(aq) to give Fe(aq)³⁺ and ClO₂ ).³¹
However, two Fe^III products are possible. One is from an
outer-sphere electron-transfer reaction to give [Fe^III(H₂O)₆³⁺]‚-
-
[ClO₂ ]. In the other path ClO₂ substitution of a H₂O
2+
coordinated to Fe^II can give [Fe^II(H₂O)₅ClO₂]_IS followed
by an extremely rapid inner-sphere electron transfer to give
-
[Fe^III(H₂O)₅ClO₂ ]_IS²⁺. The latter complex can dissociate to
3+
-
give Fe^III(H₂O)₆ and ClO₂ . In this work we can observe
the formation of [Fe^III(H₂O)₅ClO₂ ]_IS²⁺ due to its appreciable
-
molar absorptivity. This enables us to separate the inner-
sphere and outer-sphere pathways.
2+
Fa´bia´n and Gordon²² observed the formation of FeClO₂
in aqueous solutions that contained Fe(aq)³⁺ and ClO₂ and
reported a rate constant of 269 M^-1 s^-1. The rate constant
determined in this study for the formation of FeClO₂²⁺ from
the reaction of Fe(aq)²⁺ and ClO₂ is 1.5 × 10⁶ M^-1 s^-1.
Scheme 1 shows the various steps involved in the reduction
of chlorine dioxide by Fe(aq)²⁺. An electron-transfer reaction
within an inner-sphere complex must be responsible for the
However, because of the overlap between the formation
and decay reactions of the intermediate (seen in parts a and
b of Figure 6 at 260 nm), the true maximum absorbance of
FeClO₂²⁺ is greater than that observed and reported in Table
2 at 510 nm. In the kinetic study, where [Fe(aq)²⁺] is present
at much higher levels than [ClO₂], we can predict the
maximum [FeClO₂²⁺] by use of eqs 11 and 12.³²
formation of Fe(aq)³⁺ and ClO₂ . Otherwise, ClO₂^- and Fe-
-
(aq)³⁺ would have been the direct products of the ClO₂/Fe-
(aq)²⁺ reaction and no intermediate would have been
2+
2+
observed. Therefore, the rapid formation of FeClO₂
In eq 12, k_i is the rate constant for FeClO₂ formation
and k_d is the rate constant for its decay (39.3 s^-1). The
indicates an inner-sphere reaction as one of the electron-
(31) Schmitz, G.; Rooze, H. Can. J. Chem. 1984, 62, 2231-2234; 1985,
63, 975-980.
(32) Espenson, J. H. Chemical Kinetics and Reaction Mechanisms, 2nd
ed.; McGraw-Hill: New York, 1995; p 71.
Inorganic Chemistry, Vol. 43, No. 23, 2004 7549

Wang et al.
significance of k_i is discussed further in the following section.
Equation 12 permits us to predict that the inner-sphere path
is 14% of the overall reaction (rather than 12%). This value
was obtained on the basis of an iteration by use of the
conditions in Figure 4 at 500 nm ([Fe(aq)²⁺] ) 3.69 × 10^-4
2+
M, [ClO₂] ) 2.2 × 10^-5 M, FeClO₂
ꢀ
500
) 600 M^-1 cm^-1,
observed A_max ) 0.005, k_d ) 39.3 s^-1, and initial k_i ) 1.8 ×
10⁵ M^-1 s^-1). Hence the outer-sphere electron-transfer path
represents 86% (rather than 88%) after correction for this
overlap.
Figure 9. Eyring plots. (a) The electron-transfer reaction between ClO₂
and Fe(aq)²⁺ by outer-sphere and inner-sphere paths. Slope ) -4.8(4) ×
and Fe(aq)³⁺. Slope ) -8.8(7) × 10³, and intercept ) 27(3). Conditions:
[Fe²⁺] ) 0.392 mM; [ClO₂]_i ) 0.040 mM; [HClO₄] ) 0.50 M; temperature
range 5.0-25.0 °C; λ ) 500 nm.
k_i
9
k_d
Fe(aq)²⁺ + ClO₂
8 FeClO₂²⁺ 98 Fe(aq)³⁺ + ClO₂ (11)
-
10³, and intercept ) 24(2). (b) The dissociation of FeClO₂ into ClO₂
2+
-
k_d
k_d
2+
[FeClO₂²⁺] ) [ClO₂]
exp
2+
(
)
(
)
[Fe(aq) ]k_i
[Fe(aq) ]k_i - k_d
this K value and the self-exchange rate constant values of
(12)
2
k_{ClO /ClO} ) 2.0 × 10 M^-1 s^{-1 35} and k_Fe
) 5.6 (0.5 M
²⁺/Fe³⁺
-
2
2
NaClO₄, 25.0 °C),³⁶ the rate constant for the outer-sphere
electron transfer is estimated to be 1.7 × 10³ M^-1 s^-1 on
the basis of Marcus theory.³⁷ The measured rate constant
(1.3 × 10⁶ M^-1 s^-1) for the outer-sphere path is 765 times
larger than expected by simplified Marcus theory. Deviation
from the simplified Marcus theory may occur in the case of
small molecules,³⁸ where orbital overlap occurs.
Note that the literature value for the equilibrium constant
K_i was determined by the use of much higher initial
concentrations of Fe(aq)³⁺ and ClO₂^-.²² The accuracy of the
percent contribution from each of the pathways is based on
the literature molar absorptivity and equilibrium constant.²²
Resolution of Rate Constants. Although the second-order
rate constant, k^2nd ) 1.5 × 10⁶ M^-1 s^-1, is obtained by
following the formation of FeClO₂²⁺, it reflects the loss of
ClO₂ by all the reactions that consume it. Therefore, the k^2nd
Fa´bia´n and Gordon²² predicted the second-order rate
constant for the reaction in eq 2 to have a value of 1.5 ×
10⁶ M^-1 s^-1 (pH 1.0-3.5, µ ) 1.0 M, and 25 °C) on the
basis of their calculated equilibrium constant for eq 2 and
value is actually a summation of the inner-sphere path (k_i )
Fe(II)-H₂O
K_OS^Fe(II)k₁
) and the outer-sphere path (k_o )
Fe(II)
-
the measured rate constant values for the Fe(aq)³⁺/ClO₂
K_OS
k
^et). The inner-sphere rate constant k_i ) 2.0(1) ×
OS
10⁵ M^-1 s^-1 is obtained by eq 13. The R term is the fractional
contribution of the inner-sphere path (14%). From the k_i and
k^2nd values, the second-order rate constant for the outer-sphere
path is 1.3(1) × 10⁶ M^-1 s^-1.³³
2
Fe(III)
reaction (K_OS
k
-1
^{Fe(III)-H O}). This agrees with our experi-
mental results. However, they were not able to distinguish
the inner-sphere and outer-sphere paths for the ClO₂/Fe(aq)²⁺
reaction in their studies. The current study shows that the
Fe(aq)²⁺ reaction with ClO₂ is 500 times faster than what
was reported by Hoigne´ and Bader (k_rxn ) 3.0(5) × 10³ M^-1
s^-1),³⁹ who could have been misled by the decay profile of
k_i ) Rk^2nd
(13)
The Fe²⁺-H₂O exchange rate constant (k₁^{Fe(II)-H O}) is 3.2
2
-
the subsequent reaction of ClO₂ with Fe(aq)²⁺.
Fe(II)
× 10⁶ s^-1, and Fe²⁺ is expected to have a K_OS
with a
Activation Parameters. The activation parameters for the
value of 0.1 for the neutral ligand.³⁴ Hence, the substitution
2+
reduction of ClO₂ by Fe(aq)²⁺ and the FeClO₂ decay are
rate constant (K_OS^Fe(II) k₁^{Fe(II)-H O}) is estimated to be 3 × 10⁵
2
determined from the temperature dependence of the rates in
0.50 M perchloric acid. The Eyring plot in Figure 9a yields
values of ∆H_r^q ) 40(5) kJ mol^-1 and ∆S_r^q ) 1.7(2) J mol^-1
K^-1 for the reaction of ClO₂ with Fe(aq)²⁺. Because the k^2nd
value represents both inner-sphere and outer-sphere paths,
the ∆H_r^q and the ∆S_r^q obtained from the measurement of
the k^2nd values are composite parameters. The outer-sphere
path (86%) dominates the reaction, so the values of ∆H_r^q
M^-1 s^-1, which is in reasonable agreement with the measured
k_i value (2.0 × 10⁵ M^-1 s^-1). This indicates that the
substitution step (k₁^{Fe(II)-H O}) is the rate-determining step in
2
the inner-sphere path and is followed by a fast electron
transfer (k_IS^et) to form FeClO₂²⁺. The outer-sphere electron
transfer occurs with a second-order rate constant k_o ) 1.3
× 10⁶ M^-1 s^-1.
By using the corresponding standard electrode potentials,
Schmitz and Rooze³¹ estimated the equilibrium constant for
the reduction of ClO₂ to ClO₂^- by Fe²⁺ in 1.0 M NaClO₄ at
(35) Stanbury, D. M. AdVances in Chemistry Series: Electron-Transfer
Reactions; American Chemistry Society: Washington, DC, 1997; pp
165-182.
-
25 °C: K ) [ClO₂ ][Fe³⁺]/([ClO₂][Fe²⁺]) ) 3.7 × 10³. From
(36) (a) Lappin, G. In Redox Mechanisms in Inorganic Chemistry; Burgess,
J., Ed.; Ellis Horwood Series in Inorganic Chemistry; Ellis Horwood:
Chichester, U.K., 1994; p 60. (b) Jolley, W. H.; Stranks, D. R.;
Swaddle, T. W. Inorg. Chem. 1990, 29, 1948-1951. (c) Brunschwig,
B. S.; Creutz, C.; Macartney, D. H.; Sham, T.-K.; Sutin, N. Faraday
Discuss. Chem. Soc. 1982, 74, 113-127.
(33) k^2nd is the overall second-order rate constant. k_i ) K_OS^Fe(II)k₁
Fe(II)-H₂O
Fe(II)
et
and k_o ) K_OS
k
are the second-order inner-sphere and outer-
OS
sphere rate constants for the pathways of the Fe(aq)²⁺/ClO₂ reaction,
respectively. K_OS^Fe(II) is the equilibrium constant to form (Fe(H₂O)₆
‚
2+
ClO₂)_IS, k₁^{Fe(II)-H O} is the water-exchange constant for Fe(II), and k_OS
(37) Espenson, J. H. Chemical Kinetics and Reaction Mechanisms, 2^nd ed.;
McGraw-Hill: New York, 1995; pp 243-247.
et
2
is the electron-transfer rate constant for the outer-sphere pathway.
(34) Margerum, D. W.; Cayley, G. R.; Weatherburn, D. C.; Pagenkopf, G.
K. In Coordination Chemistry; Martell A. E., Ed.; American Chemical
Society: Washington, DC, 1978; Vol. 2, pp 12-13.
(38) Awad, H. H.; Stanbury, D. M. J. Am. Chem. Soc. 1993, 115, 3636-
3642.
(39) Hoigne´, J.; Bader, H. Water Res. 1994, 28, 45-55.
7550 Inorganic Chemistry, Vol. 43, No. 23, 2004

Chlorine Dioxide Reduction by Aqueous Iron(II)
Table 3. Summary of the Rate Constants and the Activation Parameters
reaction
rate const^a
∆H^q (kJ mol^-1
)
∆S^q (J mol^-1 K^-1
)
ClO₂ + Fe(aq)²⁺ f ClO₂^- + Fe(aq)³⁺
1.3 × 10⁶ M^-1 s^{-1 b,c}
2.0 × 10⁵ M^-1 s^{-1 b,d}
39.3 s^{-1 b}
40(5)^e,f
76(9)^e,f
41(1)^h,i
1.7(2)^e,f
32(5)^e,f
48(1)^h,i
ClO₂ + Fe(aq)²⁺ f FeClO₂
2+
FeClO₂²⁺ f Fe(aq)³⁺ + ClO₂
-
HClO₂ + Fe(aq)²⁺ f Cl(II) + Fe(aq)³⁺ + H⁺
ClO₂^- + Fe(aq)²⁺ f Cl(II) + Fe(aq)³⁺
3.5 × 10² M^-1 s^{-1 g}
2.0 × 10³ M^-1 s^{-1 g
a} Conditions: 25.0 °C. ^b Conditions: [HClO₄] ) 0.50 M. ^c Outer-sphere pathway for the ClO₂/Fe(aq)²⁺ reaction (k_o). ^d Inner-sphere pathway for the
ClO₂/Fe(aq)²⁺ reaction (k_i). ^e Temperature range 5.0-25.0 °C, [HClO₄] ) 0.50 M. ^f The values are for a combination of inner-sphere and outer-sphere
paths. ^g Conditions: 0.01-0.14 M [H⁺] in H₂SO₄ medium. The initial product, Cl(II), reacts further with another Fe(aq)²⁺ to give HOCl. HOCl is reduced
by 2Fe(aq)²⁺ to Cl^-. ^h These are composite values for the reactions of both forms of Cl(III) with Fe(aq)²⁺ in 0.4 M [H⁺] and µ adjusted to 1.0 M by Na₂SO₄.
Temperature range ) 20-40 °C. ⁱ ∆H_HClO ° ) 17.2 kJ mol^-1
.
2
and ∆S_r^q reflect the features of the outer-sphere path more
than those of the inner-sphere path. The Eyring plot in Figure
the composite activation parameters are not resolved for the
-
Fe(aq)²⁺ reactions with HClO₂ and ClO₂ , the dominant
q
q
9b yields values of ∆H_d ) 76(9) kJ mol^-1 and ∆S_d ) 32(5)
J K^-1 mol^-1 for the decomposition of FeClO₂²⁺ to generate
Fe(aq)³⁺ and ClO₂. The Eyring plot for Fe(aq)²⁺/Cl(III)
reaction ([H⁺] ) 0.40 M and µ ) 1.0 M (Na₂SO₄)) leads to
reaction is with HClO₂ at the acidities used. Therefore, these
activation parameters should correspond approximately to
those for the HClO₂ reaction. Table 3 is a summary of all
the rate constants and activation parameters obtained in this
study. Confidence intervals for the activation parameters were
calculated on the basis of a t-value of 2.92 at the 90% level.⁴⁰
q
the composite activation parameters ∆H_Cl(III) ) 41(1) kJ
q
mol^-1 and ∆S_Cl(III) ) 48(1) J K^-1 mol^-1 (temperature range
) 20-40 °C) as shown in Figure S3. These composite
activation paramters represent the effect of temperature on
Acknowledgment. This work was supported by National
Science Foundation Grants CHE-9818214 and CHE-0139876.
We thank Deedra Pell (a freshman honor student) for her
-
the rate constants for both Fe(aq)²⁺/ClO₂ and Fe(aq)²⁺/
HClO₂ reactions as well as on the K_a^HClO values. The
2
enthalpy for the protonation constant of HClO₂ is 17.2 kJ
+
measurement of the molar absorptivity of FeSO₄ .
mol^-1 (10-60 °C).²⁶ At 25.0 °C, the ratio of [HClO₂]/[ClO₂^-]
-
is 35.5 in 0.4 M acid and the k_HClO /k_ClO ratio is 0.18. At
2
2
-
Supporting Information Available: Figures with supplemental
data. This material is available free of charge via the Internet at
http://pubs.acs.org.
40.0 °C the [HClO₂]/[ClO₂ ] ratio increases to 50. Although
(40) Skoog, D. A.; West, D. M.; Holler, F. J. Fundamentals of Analytical
Chemistry, 7th ed.; Saunders College: Orlando, FL, 1997; pp 48-
50.
IC048809Q
Inorganic Chemistry, Vol. 43, No. 23, 2004 7551