Substitution reactions in octahedral complexes

graduate courses in chemistry.' One fascination of this area of study is the uncertainty concerning the mech- anisms of some well studied reactions. F...
2 downloads 0 Views 2MB Size
GUEST AUTHOR G. R. H. Jones

Loughhorough University of Technolosv ~n~lond

I(

Textbook Errors,

Substitution Reactions Octahedral Complexes

A

lecture series devoted to a discussion of mechanisms of reactions of inorganic complex compounds, particularly of substitution and electron transfer reactions, is now an established part of many undergraduate courses in chemistry.' One fascination of this area of study is the uncertainty concerning the mechanisms of some well studied reactions. For example, mechanisms of the familiar acid-hydrolysis reaction in aqueous solution,

+

lCo(NH3)&l'~-~+ N 2 0

72

= [CO(NH$)~ HIO]J++ X m - .

(where Xm- is a monodentate anionic ligand), still raise considerable discussion (1). Thus, when X is S80a2-, Banerjea and Das Gupta (2) favor an SN2 mechanism, and when X is F-, C1-, Br-, and NO3-, Chan (3) suggests an SN2 mechanism, involving solvenbassisted removal of the departing anion. (In the case of F-, the SN2 reaction is thought to occur simultaneously with an acid-catalyzed SE2 reaction.) On the other hand, when X is NOs-, Pearson and Moore (4) suggest a solvent-assisted dissociation mechanism (6),while Langford (I), when X is F-, Cl-, Br-, NOsand H2P04-, considers the possibility of the formation of a five coordinate intermediate which reacts very rapidly with a nucleophile (i.e., a water molecule) already present in the second coordination sphere. Although a single mechanism may not be adequate to cover reactions for a wide range of anions X, mechanisms are still controversial in specific cases. In view of the contentious nature of many such mechanisms, categorical statements in this field are dangerous, especially if they involve broad generalizations. One such generalization which appears, either directly or by implication, in a number of texts, involves a rejection of the possibility of direct substitution, in aqueous solution, of a ligand in an octahedral complex by a nucleophile other than water or OH-. A statement containing this generalization may be quoted, "In water, aquation invariably precedes substitution by anions." There is substantial evidence that, in a number of Suggestions of material suitable for this column and guest columns suitable for publication directly should he sent with as many details as possible, and particularly with references to modern textbooks, to W. H. Eberhardt, School of Chemistry, Georgia Institute of Technology, Atlanta, Grt. 30332. ' Since the purpose of this column ie to prevent the spread and continuation of errors and not the evaluation of individual texts, the sources of error discussed will not be cited. In order to be presented, an error must occur in at least two independent recent standard books.

cases, aquation (acid-hydrolysis) does precede substitution by anions (4, 6, 7). For example, the reaction (7) [Co en2 (NO?)Cl] +

+ NCS- e [Co en. (NOy) (NCS)] + C1+

appears to proceed via the steps [Co enn (NO*) CI] +

+ HtO s [Co enl (NO2) (H10)l2++ C1-

+

[Ca em (NOr) (HzO)IP+

NCS-

e [Co en,

(NO1) (NCS)I+

+ Ha0

for both cis and trans isomers. The change in optical density of the reaction mixture, a t 470 mfi, can be accounted for in terms of the stages shown. Further, with azide or nitrite ion in place of thiocyanate ion, the rate of C1- release is independent of aside or nitrite concentration, providing additional evidence for a two stage process. In certain non-aqueous solvents, the possibility of direct anion substitution appears to be accepted (8), without the initial intervention of the solvent. This may be due to the solvent (a) being a weaker nucleophile than water, (b) being a less effective solvating medium for anions (Q), thereby increasing their reactivity, (c) favoring ion-association (9) (this being related to (b) ), in which case the anion could occupy a position in the second co-ordination sheath of the complexed metal ion ( I ) , poised for immediate attack in direct competition with the solvent, (d) being incapable of hydrogen-bonding, which, in the case of water, can hold solvent molecules in position for immediate attack on the complex (10). In aqueous solution, where the water concentration is about 55 M, the situation for direct substitution may be less favorable. In spite of this, evidence of two types is available (11-16, 2), indicating that direct substitution does occur. (I) Evidence has been obtained for a five coordinat,e intermediate which is capable of discriminating between potential nucleophiles. In this case, the substitution reaction involves a dissociation mechanism. (11) The nature and concentration of the substituting nucleophile influences the rate of substitution in certain cases, and an acceptable nucleophilic order has been compiled for a range of substituting anions and molecules. This suggests that a displacement mechanism is operating in these cases. Considering (I)above, Ardon (11,I,!?) has shown that thc reaction

Volume 43, Number 12, December 1966

/

657

where X- is CI- or Br-, can occur by direct anion substitution. Evidence of mass-law retardation (17) by I- indicates the formation of a five coordinate intermediate Cr(H20)sa+. Further, the quantities of the product Cr(HZO)SX2+ found, could not come from the reaction

+

[Cr (HxO)J3+ X - -

[Cr (HsO), XIS+

+ HzO

due to the unfavorable equilibrium position of this reaction. The five coordinate intermediate must therefore be capable of reacting directly with the anion X-, as well as with the solvent. Haim and Wilmarth (13) determined the rate of acidcatalyzed aquation of the complex ion [Co(CN),N313-. On addition of thiocyanate ion, (a) the rate of disappearance of [ C O ( C N ) ~ N ~remained ]~unaltered and (b) the product contained [CO(CN)~(SCN)]~-, as well as [CO(CN)~(H~O)]~-, even in the initial stages of reaction before anation of the aquo-complex became significant. in the product The proportion of [CO(CN)~(SCN)]~increased with the thiocyanate ion concentration. These results are explained in terms of a mechanism in which water and thiocyanate ions compete for an intermediate, presumably five coordinate, whose rate of formation is independent of the presence of anions. Referring back to (11) above, Banerjea and Gupta (2) studied the reaction

+ Rn-+ [Co (NH8)6R](Sa'+ + SIOsP-

[CO(NHa)c (S*Oa)I+

in aqueous solution, with R being OH-, Cl-, NH3, HzO, and conclude that the reaction rate can be expressed by a general equation, rate = k' [Complex]

+ k" [Complex] [RI

(1)

Here [Complex] represents the concentration of the thiosulphate complex. This expression is interpreted as follows. k' is the pseudo f i s t order rate constant for aquation, and k" the second order rate constant for direct anion or ammonia substitution. When water is the only nucleophile present, the term involving k" disappears, as does that involving k' when OH- is the nucleophile. The first order dependence of the term involving k", on the concentration of the nucleophile, coupled with the fact that the values of k" increase with the nucleophilic character of R, in the order H20 < NHs < CI-

< OH-

is assumed to indicate an SN2 mechanism for substitution. Although this interpretation may be questioned on the grounds that (a) OH- probably reacts by an SN1 CB mechanism (IS), and (b) Pearson and Moore (4) have shown that substitution of nitrate by thiocyanate ion, in the complex [ C O ( N H ~ ) ~ N O ~pro]~+, ceeds almost entirely via the aquo complex, in aqueous solution, the possibility of direct substitution by an SN2 mechanism still remains. Margerum and Morgenthaler (15) studied the rate of dissociation of Fe(phen),=+ in aqueous solution, in the presence of OH-, CN- and N3-. These anions increased the rate of disappearance of F e ( ~ h e n ) ~giving ~+, a term in the rate expression dependent on the first power of the anion concentration, e.g., k = kl kZ [CN-1. This expression can be explained in terms of the reactions

+

658

/

Journal of Chemicol Education

phen

where kz = (KG,-) (kc,-). For a given anion concentration, the observed rate constant k increases with change of anionin the order N3- < OH- < CN-. Here, direct anion substitution appears to have occurred. The preceding examples all involve transition metal complexes. That direct substitution can also occur in an octahedral complex of a nontransition element in aqueous solution, by nucleophiles other than water, is shown by the following example. Pearson, et al. (16) studied the rate of the substitution reaction and observed a marked dependence of rate of disappearance of [Si (acac)J+ on the nature of any nucleophiles present. A range of anionic and molecular nucleophiles were studied, and the order of nucleophilic activity was explained in terms of changes in basicity, polarinability and alpha effect (19). This indicates an initial bimolecular nucleophilic attack at the octahedral Sir' atom, resulting in the displacement of one end of an acetylacetonate chelating ion. Rapid loss of the displacing nucleophile and the acetylacetonate groups follows, yielding Si(OH),. Again, a direct substitution by the nucleophiles studied, e.g., OH-, H02-, RTH2NH1, HPOe2-, F-, NO2-, S20?, is proposed. This brief discussion is not meant to be exhaustive. It is simply intended to help to prevent the dissemination of the idea that, for octahedral complexes in aqueous solution, all nucleophilic substitution reactions might go via an aquo complex. Literature Cited

(1) LANGFORD, C. H., Inorg. Chem., 4,265 (1965). (2) BANERJEA, D. AND DAS GUPTI, T. P., J . Inorg. Nucl. Chem., 27,2617 (1965). (3) CHAN,S. C., J. Chem. Soc., 2375 (1964). R. G., AND MOORE,J. H., I ~ O T Chem., R. 3, 1334 (4) PEARSON, (1964). W. E., G i D \V.~LLACE, W. J., Can. J . (5) JONES,T. P., HARRIS, Chem.. 39. 2371 (1961). (6) ETTLE, 6. W. AND JOHNSON, C. H., J. Chem. Soc., 1490 (19.19). , - -,~ ~ ~

(7) BASOLO, F., STONE, B. D., BERGXINN, J. G., AND PEARGON, R. G., J. Am. Chem. Soe., 76, 3079 (1954). (8) BASOLO, F., AND PEARSON, R. G., Advances in Inorg. and Radiochem., 3, 43 (1961). A. J., Quad. Rev., 16, 163 (1962). (9) PARKER, A. W.. A N D BMOLO. (10) . . ADAMSON. . F... Acta. C h m . Seand... 9.. 1261 (1955). ' (11) ARDON, M., Pwc. Chem. Soc., 333 (1964). M., Inorg. Chem., 4, 373 (1965). (12) ARDON, W. K., Inwg. C h m . 1,583 (1962). (13) HAM,A,, AND WILMARTH, (14) HAIM,A,, AND TAUBE,H., Inorg. Chem. 2,1199 (1963). D. W., AND MORGENTHALER, L. P., "Advances (15) MARQERUM, in the Chemistly of the Co-ordination Compounds," The MacMillan Co., New York, 1961, p. 481. R. G., EDGINGTON, D. ?I AND .,BASOLO, F., J. .4m. (16) PEARSON, Chem. Soc. 84, 3233 (1962).

(17) INGOLD, C. K., "Structure and Mechanism of Organic

Chemistry," Cornell University Prem, Ithaca, N. Y., 1953, p. 362.

(18) BASOLO, F., SZL?V~Y O ~ P T O Q1% T Chemistry, ~SS 2, 21 (1964). (19) EDWARDB, J. O., AND PEARSON, R. G., J. Am. Chem. Soc., 84, 16 (1962).

Volume 43, Number 1 2 , December 1 9 6 6

/

659