Kinetics of the Hydrolysis of Hexachloroantimonate(V)

1848

H. M. NEUMANN AND R. W. RAMETTE [CONTRIBUTION O F

THE CHEMICAL

LABORATORIES OF

EORTHWESTERN

Vol. 78

UNIVERSITY AND CARLETON COLLEGE]

Kinetics of the Hydrolysis of Hexachloroantimonate (V) BY H. M. NEUMANN AND R . W. RAMETTE RECEIVEDNOVEMBER 11, 1955 Three methods (spectrophotometric, amperometric and solvent extraction) for measuring the kinetics of hydrolysis of SbC16- were investigated. T h e spectrophotometric method, which was superior t o t h e other methods, was used for extensive measurements of the kinetics at 25" under varying conditions. T h e rates were determined under conditions where the reaction was pseudo first order; i.e., the rate = kh[SbCl6-]. Hydrogen. ion accelerates the hydrolysis; at a total chloride concentration of 6 M the rate constant k h = (3.9 0.8[H+]) X min.-'. A t a total chloride concentration of 9 M, k h = (5.3 -I- l.fi[H+])X . 1 0 T 3 mjn.-I. Antimony(II1) also accelerates the reaction, SbC13 apparently being the effective form. Mechanisms, consistent with these observations, are proposed.

+

The slow rate of hydrolysis of the hexachloroantimonate(V) ion, SbCI6-, was first reported by Weinland and Schmid.' Recent work2 on the equilibrium aspects of the hydrolysis of SbC16- has also indicated the feasibility of investigating the kinetic aspects of the hydrolysis. More detailed knowledge of this hydrolysis is of value because of its relation to the rhodamine B method of analysis for antimony, and because of its relation to the radioactive exchange between Sb(II1) and Sb(V).4 Of even greater value is the fact that this complex provides a convenient case for studying the factors affecting the kinetics of hydrolysis of halo-complexes. This type of reaction has not previously been studied extensively, primarily because of the rapid rate of reaction of most halo-complexes. As a result of this study of SbC16- some of the mechanistic features of the hydrolysis reaction are now evident.6

Experimental Reagents.-The Sb(II1) used for stock solutions was prepared from SblOS t h a t had been purified by the method of S c h u l ~ m a n n . ~The Sb(V) stock solutions were prepared by two methods: (1) by chlorine oxidation of a concentrated Sb(II1) solution, followed by boiling to remove excess C12, and then dilution with hydrochloric acid, and ( 2 ) directly from Baker and ildamson reagent grade SbCls. The hydrochloric acid and lithium chloride, which were used without further purification, were Baker Analyzed reagent and Mallinckrodt analytical reagent, respectively. The LiC1HC1 mixtures were prepared by adding by means of a buret the desired volume of concentrated stock solutions of the two. The conceiitrations of the stock solutions had previously been determined bl- titration with standard A g X O B and standard NaOH. Rate of Hydrolysis by Extraction Method.-It has been shown3 t h a t the well-known rhodamine B method extracts the anion SbC16- from h!-drocliloric acid solutions of Sb(V) and that the hydrolyzed species do not react with the dye to :I measurable extent. Therefore it is sound in principle to follow the hydrolysis of SbC1,- using this method. A solution of 0.0001 M SbCle- in 6.1 .1f hydrochloric acid was prepared by dilution of 0.5 ml. of 0.Ul .11 SbC16- in concentrated acid with 49.5 ml. of 6.1 -21acid. As the hydrolysis reaction occurred, 1-ml. samples were withdrawn a t intervals and analyzed by the rhodamine B method. The extraction required only about one minute, during which time the formation reaction does not occur to a n appreciable extent. The absorbance of the benzene extract was measured a t 564 mp with a Beckman Model B spectrophotometer. (1) R . F. Weinland a n d H. Schmid, Z . anorg. allgem. Chem., 4 4 , 37 (1903). (2) €3. M . h-eumann, THIS J O U R N A L , 76, 2611 (1954). (3) R . CI'. R a m e t t e a n d E. B. Sandell, Anal. Chim. Acta, 13, 45.5, (1955). ( 4 j 11. M N e u m a n n and H Brown, THISJ O U R N A L , 78, 1843 (19.56). (5) Some of t h e resiilts of this w,ork were reported a t t h e Analytical Symposium, Syracuse University, June, 1935. ( G ) I< Schuhrn;inn, 'TIITSJ O U K N A I . , 46, 5 2 (1924).

Rate of Hydrolysis by Amperometric Method.-It was discovered t h a t Sb( V) in concentrated hydrochloric acid is reduced t o Sb(II1) a t the rotated platinum electrode to give a current voltage curve with a well-defined diffusion region. The diffusion current is proportional t o the concentration of SbCls-. It is possible to follow the hydrolysis of the latter by this method because the hydrolyzed species are reduced irreversibly at more negative potentials. This is made clear by consideration of Fig. 1. Linde nitrogen was used to remove oxygen from the solutions, which were prepared by dilution of a small volume of a concentrated hydrochloric acid solution of Sb( V) with a large volume of hydrochloric acid of the appropriate concentration. During a kinetics run the applied potential was constant at f0.1 volt vs. S.C.E. and the current was measured with a Weston Model 430 microammeter. The circuit was open except during measurement to minimize formation of Sb(II1) by the electrode reaction. Rate of Hydrolysis by Spectrophotometric Method.Utilization of a spectrophotometric method, based on the ultraviolet absorption characteristics of SbCle- and its hydrolysis products, has been discussed previously.* Measurements were made with a Beckman Model DU spectrophotometer using fused silica cells having a light path of one cm. The cells were maintained at constant temperature in the spectrophotometer b y means of a water jacket, through which water from a therniostated bath (25.0 f 0.2") was circulated. T o begin the reaction a small volume of a 0.5 M Sb(V) stock solution in concentrated HC1 was added to a solution of the desired composition. For solutions containing only HC1 and LiCl as additional components, a 20-microliter portion of the Sb(V) stock was added to 25 ml. total. "Abwrbance" readings at this concentration (4 X M) were convenient in the wave length region 290-320 mp. Data were taken at time intervals dependent on the rate, and a t several wave lengths. For the slower reactions data were taken a t wave lengths of 290, 300, 310 and 320 m p . For the faster reactions, where the time interval between readings was smaller, only two wave lengths, 300 and 310 m p , were used. For experiments involving antimony( 111)it was necessary to use larger concentrations of Sb(V) so t h a t the latter would still be the principal light absorbing species. Solutions 0.01 and 0.02 M in Sb(V) were used. D a t a were taken at several wave lengths in the region 340-400 mp, the number of wave lengths used for a n y one experiment being from one to five depending on the rate. Treatment of Spectrophotometric Data.-Although there are several reactions actually occurring, the system in essence is t h a t of two reversible first-order reactions kh

A

Z

B

kr In this case A is SbCla-, B is the mixture of hydrolytic species, k h is the pseudo first-order rate constant for hydrolysis of SbCls-, and kf is the pseudo first-order rate constant for formation of SbCls-. A plot of log Id - .4ml us. time, where d is the absorbance, gives the expected straight line, and from the slope of the line ( k h kt', can be calculated. In general we are interested in obtaining k h rather than (kb k f ) . For reactions where kt is small with respect to k h , correspoiiding to reactions where the hydrolysis is essentially complete at equilibrium, the plot just described is s a t -

+

+

May 5, 1956

1849

HYDROLYSIS OF HEXACHLOROANTIMONATE(V) : KINETICS

30

1 .o

25

@ 20

I

/

I

0.8

+-’

8

15

8

10

t:

0.6

5

+

0.4 0.3 0.2 0.1 0 0.1 0.2 Voltage us. S.C.E. Fig. 1. Current-voltage curves obtained a t various times M SbCls- in 6.1 M hydroduring the hydrolysis of 2 X chloric acid, using rotated platinum electrode: A, after 10 min.; B, 1.5 hours; C 3 hours; D, 24 hours (a); E, residual current. 0.6

0.5

isfactory for the determination of k h . Solutions where the concentration of HC1 is 6 M o r smaller fall into this category, and the data were treated accordingly. For each experiment a rate constant was calculated from the data a t each wave length, and an average value then taken. The total spread in the values obtained a t the several wave lengths was generally about 5% of the average value. When kf is comparable to k h one plots log / A - ABI v s . time, where A B is the absorbance the solution would have if all A were converted to B. A B can be calculated from the data and interpretation thereof given in an earlier paper,2 but is clearly dependent on the assumptions and interpretation involved in that work. The plot of log IA - A B / vs. time is initially a straight line (from the slope of which one can calculate k h ) , but it curves when the rate of the reverse reaction is no longer negligible. The values of k h obtained by this method are limited in accuracy because of two causes: (1) graphical determination of the initial slope is difficult, particularly when the equilibrium amount of SbC16- is large, and (2) the value of k h will be dependent on the value chosen for AB. The only experiments where this method was necessary were those in which the chloride ion concentration was 9 M. The likely accuracy of the k h values has been estimated in the following way for each of the two limiting factors stated above: (1) The values of k h calculated from data a t the various wave lengths fell within 1 5 % of the average value. (2) After making the calculation of k b from the best possible estimates of A B a t the various wave lengths, the calculation was repeated using as new values of A B 75% of the previous values. The new values of k h were uniformly lower by about 10% of the earlier value. Considering both these effects i t is felt that the k h values stated are reliable to zk20%. Figure 2 provides an example of the graphical treatment of the data. The data were taken a t 300 mp on a 5 iM HC14 M LiCl mixture.

Results Comparison of Methods. (1) Extraction Method. -A plot of log ( A - A , ) vs. time, where A is the absorbance of the benzene extract, was linear with a slope corresponding to a value of 0.0093 min.-’ for the rate constant k h in 6.1 M HCI. This is in good agreement with the values given below for the other methods. Because of the relative difficulty of this method no further experiments were tried. (2) Amperometric Method.-Plots of log (i i,) vs. time, where i is the measured current, were linear. The values obtained for the rate constant were in agreement with those by the spectrophotometric method except a t low acidities. F o r example, for hydrochloric acid concentrntioris of 6,

y 0.4

0.3

0.2

I

I

I

I

i1 U

PO 31) 40 50 60 Time, min. Fig. 2.-Example of treatment of spectral data to obtain the rate constants. The data were taken a t 300 mp on a plot has been 5 M HC1-4 M LiCl mixture. The (A - A displaced upward for convenience in plotting. 10

4 and 2 M (chloride constant a t 6 M using lithium chloride) the values of the rate constant were 0.0099, 0.0072 and 0.0042 min.-’, respectively. (3) Spectrophotometric Method.-Neither of the previous methods appeared t o be capable of yielding results as precise as those of the spectrophotometric method. The latter method was thus the one used for the extensive measurements reported below. Dependence on Acidity.-Cheek7 has measured the rate of hydrolysis of SbC16- in hydrochloric acid solutions, and observed that the rate increases with increasing concentration of the acid. I n the course of our work several similar experiments have been performed. Figure 3 shows these results. With these data alone it is difficult to account for the observed trend, since [H+], [Cl-] and the ionic strength are all changing a t once. Experiments performed a t constant ionic strength and constant chloride concentration ate more valuable. This was done, using HCI-LiCI mixtures, for total chloride concentrations of both 6 and 9 hf,two sets of experiments being performed a t each concentration. LiCl is the best chloride for such mixtures since data from the literature* shows that for HCl-LiC1 mixtures of constant ionic strength, varying the ratio of HCI and LiCl changes only slightly the value of the mean ionic activity coefficient of HC!. (7) C. H . Cheek, P h 73 Thesis, Washinxton IJnirersity, St Louis, Janiiary, 19.i3. (8) 1%.S Ilarnrd and 8 . B . Owen, “ T h e I’hysical C h e m i s t r y 01 Elrctrolytic~Soliltions,” Reinhrdd Polil. Cor[) , S r w Y,,rk, N Y , 1Lt:Xl

H. M. NEUMA"

1850

AND

R. W. RAMETTE

Vol. 78

18

tions, the straight line corresponding to the equation k h = (5.3 4- 1.6 [H+]) X min.-I is consistent with the data obtained. A scheme of reactions that would account for the observed variation of k h with [H+] is

16

SbCls-

I

I

I

I

I

I

I

1

20

ki

-+

C1-

+ SbC16 (followed by rapid reaction

_. 14 I

d

HSbCl6

n-

X

+

SbC16-

-5 12

ka

--+-HCl

of SbCI5 with water) (I) K H " _C HSbC16 (11)

-I- SbC15 (followed by rapid reaction

10

of SbC&with water)

$ 8 6

+

4

1 Fig. 3.-Rate

2

3

4 5 6 7 8 HCl, M . constant for hydrolysis as a function of HC1 concentration.

The results of the experiments in 6 M chloride solution are given in Table I. When the observed pseudo first-order rate constant is plotted us. [H+], one obtains a straight line that corresponds to the equation k h = (3.9 0.8[H+]) X min.-'.

+

T-LE I RATEO F HYDROLYSIS O F SbCl6- I N SOLUTIONS CONTAINING 6 M C1kh X 100 (mim-1) 2nd set

IH +I

1st set

1

4.8 5.4 6.3 7.0

2 3 4 5 6

..

8.7

TABLE 11 RATEO F HYDROLYSIS O F SbCla- I N SOLUTIONS CONTAINING 9 MC1[H+]

k h X lO'min.-l 1st set 2nd set

.. 7.2 8.7 10.0 11.6 12.5 15.3 15.6 21.3 19.0

5.3 6.9 7.9 9.8

12.3 12.6 13.8 14.4 19.8 23.1

ksq X 103

Hz0

+ SbCb-

__

+

Sb(H20)ClS (1) (followed by rapid loss of H + )

SbCbHz0

ki + C1-

+ H+ k1

K

4-HSbCla + HCl

HSbCla

(2)

+

Sb(Hz0)Clb (3) (followed by rapid loss of H + )

The same restrictions apply to equation 2. These two schemes obviously differ only in whether the first and third reactions are considered to be of the S N 1 or S Ntype. ~ The rate going to equilibrium can be obtained as described in the Experimental section, the rate constant, keq, so obtained is given by k,, = k h kr. For any given experiment one can then obtain both k,, and k h , and hence kf by difference. This was done for the second set of experiments in 9 M chloride in order to observe the dependence of kr on [H+]. The purpose was t o obtain additional evidence in regard to the first hydrolytic form of Sb(V) present in these solutions. If the first hydrolytic species is Sb(OH)Clh-, as is indicated in equilibrium studies,2 then the equilibrium ultimately attained is SbC16H20 Sb(0H)Cls- 4- C1- f H + At equilibrium kh[SbCls-] = kf[Sb(OH)C1,-j, so that kr/kh = [SbCl6-]/[Sb(0H)Cl5-]. But from the equilibrium constant expression

+

4.7 5.4 5.9 7.1 7.8 8.5

The results in 9 M chloride are similar, and are given in Table 11. The values of k h are less accurate here because the initial slope must be used, and particularly a t the higher acidities where the hydrolysis is not extensive. Considering these limita-

0.01 1 2 3 4 5 6 7 8 9

(111)

The equilibrium reaction (11) must be rapid with respect t o reactions (I) and (111), and the equilibrium such that the amount of HSbClc is small with respect to the amount of SbCls-. These conditions would lead to the equation k h = k1 k&[H+]. Whether the species HSbCI6 should be regarded as a true chloro-acid or as merely a transition state cannot be decided. Because the dependence on water concentration remains undetermined the following scheme would also be consistent with the results

2nd set

kf X 103

kdkh

5.3 9.1 12.6 21.5 27.2 35.7 47 53 76 100

0.0 2.2 4.7 11.7 14.9 23.1 33 39 56 77

0.0 0.3 0.6 1.2 1.2 1.8 2.4 2.7 2.8 3.3

+

[SbCl~-]/[Sb(0H)Cls-] = K

aa+uci-

= K'[H+] aHtO

assuming that the activity coefficients are constant in these mixtures. It would then be expected that kf/kh would show a linear dependence on [H+]. The ratio kt/kh is not known with great accuracy; the limitations on kh have been discussed, and the accuracy of kf is limited because it is obtained by taking the difference between k,, and k h . Bearing these limitations in mind, the data of Table I1 are consistent with kf/kh being directly proportional to [€I+].

May 5, 1956

HYDROLYSIS OF HEXACHLOROANTIMONATE (V) : KINETICS

If Sb(HzO)Cls, rather than Sb(OH)ClS-, were the first hydrolytic species, k f / k h should be independent of [H+]. As a result i t is clear that the amount of Sb(HzO)C&, must be small with respect to the amount of Sb(OH)C!16-. Or expressing the same thing in another way, Sb(H2O)Cls is a strong acid in these solutions. Although these kinetic data support the equilibrium data with respect to the identity of the first hydrolytic species, there is a disagreement as to the amounts of SbCls- and Sb(OH)C16- present a t equilibrium. Using the ratio of k f / k h = 3.2 in 9 M HCI, obtained by drawing the best straight line through the kf/kh os. [Hf] data, one calculates that 76% of the Sb(V) is present as SbCl6- a t equilibrium, whereas the equilibrium data gave a value of 60%. Since in both calculations an assumption was involved about the absorbancy of Sb(OH)Cl6- at 300 and 310 mp, various trial values were assumed in an attempt to obtain greater consistency between the kinetic and equilibrium data. All these attempts only led to other difficulties, such as greater disagreement between the rate constants determined from data a t the two wave lengths for a given experiment. There would seem to be two possible reasons for failure to achieve complete consistency : (1) there are small amounts of other Sb(V) species which have not been taken into account in the spectral analysis, or ( 2 ) the spectrum of an individual species changes somewhat as the HCl concentration changes. The conclusions resulting from the spectral analysis2 are probably correct in so far as the identification of the predominant species is concerned, and for a semi-quantitative estimate of their amount as a function of acidity. The values of the equilibrium constants are questionable within a factor of two or three. The value of the equilibrium constant

is 2.2 X lo4 from the kinetic data as compared to 4.5 X lo4from the equilibrium data. The former is more reliable since the kinetic data are less sensitive to the assumptions involved. 'Dependence on Sb(II1).-Because of the importance of the hydrolysis in the understanding of the radioactive exchange between Sb(II1) and Sb(V),4 the effect of Sb(II1) on the hydrolysis was investigated. A marked effect was observed. Table 111 gives k h for various HCI solutions containing 0.0385 M Sb(II1). The accelerating effect is observed to increase with decreasing acidity, the reverse of the behavior in the absence of Sb(II1). T h a t the dependence on the Sb (111)concentration is first order is demonstrated by the data given in Table IV, in particular by the constancy of the values of Sb(III)/(kh - KO). In the table ko is the rate constant when Sb(II1) is absent. The quantity ( k h - KO) is the one of interest since i t is the rate constant for the reaction proceeding by an Sb(II1)catalyzed mechanism. Since we have seen already that hydrogen ion can catalyze the hydrolysis by attack on chloride, i t is

1851

TABLE I11 RATE OF HYDROLYSIS O F SbCle- I N HCl SOLUTIONS CONTAINING 0.0385 M Sb(II1) [H 'I

kh

k X 10' (min.-I) ko b

6.17 5.35 4.55 3.51 2.63 1.78

10.8 14.4 30 87 220 >3504

9.6 7.0 5.2 3.9 3.0 2.5

(kh

- ko) 1.2 7.4 25

83 217 >350

Formation of precipitate after 2.5 min. resulted in only a limiting value being obtained. Values taken from the curve of Fig. 3.

TABLE IV RATEO F HYDROLYSIS OF SbClr- I N 2.2 M HCl CONTAINING VARYING CONCENTRATIONS OF Sb(II1) k b X lo1 (kh - ko) X 101 j s m l [SWW 1 (min. -1) (min-1) (kh - ko) ...... 2.7 0.0 ... 0.000377 5.7 3.0 0.126 .00188 17.8 15.1 ,125 31 28 .134 .00376 76 73 .00934 .128 141 138 .0185 ,134

reasonable that a Lewis acid such as SbC1, might also serve as a catalyst in the same way, The fact that SbCL can be separated readily from HC1 solutions of Sb(II1) by volatilization suggests that a measurable amount of the Sb(II1) actually is present as SbC13. At high HC1 concentration essentially all of the Sb(II1) is present as SbC14-.9 As the acidity decreases a n increasingly larger fraction of the Sb(II1) occurs as SbC13, leading to the observed rate dependence exhibited in Table 111. The transition state involving SbCl6- and SbC13 is visualized to be C&Sb-CI~bC&-, ;.e., to have one bridging chlorine atom. Because SbC15 is a much stronger Lewis acid than SbC&the transition state probably splits into the fragments SbClaand SbC18 many more times than into the fragments SbC16 and SbCL-. It would be anticipated on this basis that any Lewis acid would catalyze the hydrolysis of SbC&-. The difficulty in demonstrating this is that most Lewis acids will not exist as such in the solutions used. Addition of 0.02 M Sn(1V) t o 4.7 M HCI was found to have no effect on the rate, presumably because insufficient Sn(1V) existed as SnClr. Addition of 0.02 M Al(II1) to a solution originally 1.2 M in HCI gave a rate 10% larger than that in 1.2 M HCI alone, but this small increase is most likely due to an increase in the hydrogen ion concentration as a result of the hydrolysis of the added AIC13 itself. Investigation of the kinetics of hydrolysis of other halo-complexes would be worthwhile to determine t o what extent the mechanistic features reported here are unique to SbCls- or are common to other halo-complexes. EVANSTON, ILLINOIS NORTHFIELD, MINNESOTA (9) G.P. Haight, Jr., THISJOURNAL, 71, 3848 (1953).