Free radical mechanism in the acid-catalyzed redox decomposition of

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2272 Inorganic Chemistry, Vol, 11, No. 9, 1972 mined the structures of a number of complexes with coordinated nitric oxide..' On the basis of their X-ray data and infrared stretching frequencies they7c have proposed the following criteria: NO+ complexes have v(NO) in the range 1600-1845 cm-l and for NO- complexes u(N0) is in the range 1525-1720 cm-l. Therefore, i t is inadequate to use v(N0) solely to determine the mode of coordination in the region 1600-1720 cm-l. We may conclude, however, that NO is coordinated as NO+ in our nitrosyl complexes. Reactions of tetracyanoethylene and fumaronitrile with IrX(CO)(P(CbHb)3)2 (X = C1, Br, I) have been studied 'extensively. A number of new compounds have been isolated and characterized in these and similar reactions. TCNE will add to [ I ~ C ~ ( N O ) ( P ( C ~ H Lto) ~give )~]+ [IrCl(NO)(P(C6Hb)&TCNE]C104. There is a change in the bonding of NO to iridium upon coordiation as evidenced by the change in u ( K 0 ) from 1902 to 1595 cm-l. It seems plausible that this structure would be similar to the bent coordinated NO as determined crystallographically in [IrCl(CO) (NO) (P(C6H5)3)2]BFd6 and that NO is coordinated as NO- here. However, such proposals must be vindicated by crystallographic study. The addition of the weaker Lewis acid fumaronitrile to [IrCl(NO) (P(C,Hj)&]+ produced no reaction, in contrast to [IrCl(CO)(P(C6&)3)2] which forms a stable compound. This decrease in chemical reactivity is consistent with previous reports on this complex.2e The decrease in apparent chemical reactivity is probably due to the positive charge on the complex and the resultant decrease in electron density on the metal. For example, this complex shows no tendency to combine with OzjZcwhereas the uncharged complex RuC1(NO) (P(C&)3)2 forms an irreversible adduct with O Z . ~ Acknowledgment.-We are indebted to Professor Abbas A. El-Awady for helpful discussions throughout the course of this research. (7) (a) D. M. P. Mingos and J , A . Ibers, Inovg. Chem., 10, 1035 (1971); (b) D. M . P. Mingos, W. T. Robinson, and J. A. Ibers, ibid., 10, 1043 (1971); (c) D. M . P. Mingos and J. A, Ibers, ibid., 10, 1479 (1971). (8) K. R . Laing and W. R . Roper, ibid., 7, 1556 (1968).

CONTRIBUTION FROM THE DEPARTMENT O F CHEMISTRY, BOSTOSUNIVERSITY, BOSTON, MASSACHUSETTS 02215

Free Radical Mechanism in the Acid-Catalyzed Redox Decomposition of

Tris(oxalato)cobaltate(III) Ion in Aqueous Solution1 BY NAXCYS. ROWAN, ROKALD M. MILBURN,* A X D MORTON 2 . HOFFMAN Received Januauy 11, 1972

Although there has been some dispute concerning the detailed path by which the acid-catalyzed redox decomposition of C O ( C Z O ~is ) ~initiated,* ~there has been general agreement up to now that the overall mech(1) Supported by the Kational Science Foundation through Grants G P 19878 and GP 11213 (2) A detailed discussion, which makes it clear t h a t the initiation process occurs in steps, will be fully presented in a separate communication.

NOTES anism involves production of a free radical (C204- or COZ-) which reattacks the substrate to form additional C O ~ + . ~In- ~simplest terms this process may be represented ki

C0(CzOa)a3-----f

czo4-

+

c02+f CzO4kz

cO(c~04)3~-

eo2+

+2c~04~-

+ 2c02 f 3czo4*-

(11

(2)

where Co(C~04)3~may be taken here to include protonated and ring-opened forms, C Z O ~includes ~HC2O4and H2C204, and ( 2 2 0 4 - includes its protonated form (or CO2- and C02H). The basis for this free radical mechanism appears to have arisen largely by analogy to the photochemical d e c o m p ~ s i t i o nand ~ ~ ~ to other oxalate reactions'O in which free radicals have been implicated. Some additional support has been offered by the observation that the thermal decomposition leads to other processes which are accepted as involving free radicals, such as vinyl polymeri~ation.~ Recently Hin-Fat and Higginson" have advanced the hypothesis that the thermal decomposition does not involve free radicals a t all. The key observation, cited by these authors for both C O ( C ~ O ~and ) ~ ~c O-( c z 0 4 ) 2 (H20)2-, is a deviation from first-order behavior as seen by curvature in plots of log (A, - A,) vs. time (where A = absorbance). The fact that wholly linear plots could be obtained by addition of a term inverse in complex concentration, together with the effect of changes in reaction conditions on the magnitude of this term, led these authorsll to favor a mechanism involving a concerted three-center redox reaction between the substrate and a ring-opened species. At appropriate relative concentrations of the reactive species, with 0 2 as an added scavenger, reactions 3 and 4 can predominate over (a), where 2k4 = 1 X l o 9 M-' CzOa- -k 02

ka ----f

2C02 $. 02-

(3)

+ cz04'-

(4 1

ka

2CzOa-

d

2c02

sec-l l 2 and ( 3 ) is assumed to be very efficient by analogy to the COz--O2 reaction.I3 In highly acidic solution, the 0 2 - radical will exist in its HzOz+ form14 which does not appear to be effectivein reducing simple Co(II1) complexes.1b Thus, the formation of Co2+in the presence of 0 2 from secondary radical reactions is of negligible contribution.I6 Here, in the slow thermal (3) T. B. Copestake and K , Uri, Pvoc. R o y . Soc., Sev. A , 228, 252 (1955). (4) A. W.Adamson, H. Ogata, J. Grossman, and R. Newbury, J . Inovg. Nucl. Chem., 6, 319 (1958). (5) F. D. Graziano and G. M. Harris, J . P h y s . Chem., 68, 330 (1959). (6) I. G. Margulescu a n d T. Oncescu, 2. P h y s . Chem. (Leipzig), 214, 238

(1960). (7) W. Schneider, Helu. C h i m . A d a , 46, 1863 (1963). (8) (a) C. A. Bunton, J. H. Carter, D . R . Llewellyn, A . L. Odell, and S. Y. (1964); (b) J. Aggett and A . L. Odell, J . Chem. Yih, J. Chem. S O C .4622 , Soc. A , 1415 (1968). (9) H . G. Kruszyna and R . M. Milburn, Inovg. Chem., 10, 1578 (1971). (10) H. Taube, J. Ameu. Chem. Soc., 70, 1216 (1948). (11) L. Hin-Fat and W. C. E. Higginson, J . Chem. SOC. A , 2836 (1970). (12) N. Getoff, F. SchwBrer, V. 311. Markovic, K. Sehested, and S. 0. Nielsen, J . P h y s . Chem., 75, 749 (1971). Keaction 4 for the protonated radical is slower (2k < 107 M - 1 sec-1) although 2h(COsH f COzH) = 4 X 109 M - 1 sec-1. (13) A . Fojtik, G. Crapski, and A . Henglein, J. P h y s . Chem., 74, 3204 (1970). , (14) B. H . J. Bielski and J . M. Gebicki, Adsen. Rediat. Chem., 2, 177 (1970). (15) N. Zevos, J. P h y s . Chem., 72, 1506 (1968). (16) I. M. Kolthoff, E. J , Meehan, and 41,Kimura [ J . P h y s . Chem., 76, 3343 (197l)l report t h a t decomposition of acidic solutions of Co(Cz04)aain t h e presence of oxygen leads t o the production of Hz02, which is presumed t o arise from t h e disproportionation of HOz.

Inorganic Chemistry, Vol. 11, No. 9, 1972 2273

NOTES reaction where the steady-state concentration of the C204- radical would be very low, (4) is of no concern. However, i t is easy to see that i f the radical mechanism decomposition in i s valid, then the rate of Co(C~04)3~deoxygenated solutions would be twice as fast as in the presence of 0 2 as long as kz[Co(C~04)3~-] 90% of reaction when the solution is continuously purged with Nz, while curvature begins after 78% in nondeaerated solution and after 66% when 0 2 is bubbled through t h e solution continuously.

CONTRIBUTION FROM THE W. A. NOYESLABORATORY, UNIVERSITY O F ILLINOIS, URBANA, ILLINOIS 61801

A New Synthesis of 1,4,8,11 -Tetraazacyclotetradecane (Cyclam) via the Nickel(I1) Complex BY E. KENTBAREFIELD

Received January 17, 1972

We wish to report a new synthesis of the title compound, I (hereafter cyclam). This ligand or the nickel

L N

NA

HUH I

complex which is the precursor may be obtained by the template synthesis outlined in the scheme of eq 1-3. This ligand is a highly desirable one for a variety of physical studies which require a complex with a planar array of donors and minimal steric requirements for