X-ray photoelectron spectroscopic study of cobalt(II) Schiff base

Inorganic Chemistry 0 (proofing), ... Richard S. Magliozzo , John McCracken , and Jack Peisach ... Structural isomers of 1:12 and 2:18 heteropoly anio...
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An X-Ray Photoelectron Spectroscopic Study of Cobalt( 11) Schiff Base Complexes and Their Oxygenation J. H. Burness, J. G. Dillard,* and L. T. Taylor* Contributionfrom the Department of Chemistry. Virginia Polytechnic Institute and State University, Blacksburg, Virginia 24061. Received March 26, 1975

Abstract: A series of p-peroxo and superoxo complexes of cobalt Schiff base compounds has been studied by X-ray photoelectron spectroscopy. The binding energies of cobalt core electrons have been shown to be dependent on the nature of the Schiff base ligand which is coordinated to the cobalt ion. Co 2p3/2 binding energies increased by 0.9-1.9 eV when the Co(I1) complexes were oxygenated, indicating that the oxygenation process can be described by an oxidative addition type of interaction between oxygen and cobalt. This description is also supported by a comparison between the Co 2~312binding energies in the cobalt-oxygen complexes and in some structurally similar cobalt(II1) complexes. Deconvolution of the 0 lsl/2 peak from the dioxygen complexes has shown that superoxo oxygen atoms exhibit a Isl/2 binding energy approximately 1 eV higher than that found for p-peroxo oxygen atoms.

The oxygenation of cobalt( 11) complexes has yielded to date reversible and irreversible 1:l and 2:1 (Co:Oz) dioxygen a d d ~ c t s .The ~ reaction whereby these materials are formed is generally believed to be an oxidative addition wherein the cobalt ion is oxidized to a certain extent which is dependent on the electronic nature of a given cobalt(I1) p r e c ~ r s o r . ~Since - ~ the technique of X-ray photoelectron spectroscopy (XPS) has been used to describe the electronic environment in a large number of transition metal comp l e ~ e s an , ~ investigation using XPS seemed appropriate for the study of charge distribution in cobalt complexes and their corresponding dioxygen adducts. It was expected that correlations could be made between cobalt and oxygen coreebectron binding energies and parameters such as the extent of electron delocalization between cobalt and oxygen, reversible vs. irreversible behavior, and the differences, if any, between p-peroxo and superoxo complexes. The only previously reported l o XPS study of cobalt-dioxygen complexes has dealt with the binding energies of Co(bzacacen)” and Co( bzacacen)O2py evaporated from methanol and pyridine, respectively. The investigators noted a binding energy increase accompanying oxygenation but it was pointed out that the Co(bzacacen) probably contained a Co(1II) impurity. We have undertaken a systematic study of the electronic charge distribution in a series of four-coordinate and fivecoordinate cobalt( 11) complexes and their oxygenation products, as well as some structurally similar cobalt(II1) complexes. The results of this investigation present unambiguous evidence that the cobalt(I1) ion is oxidized during the oxygenation process. Although the transfer of an electron from cobalt to dioxygen might not be 100%complete in the adducts which have been investigated, our results clearly show that the dioxygen adducts should not be formulated as complexes in which a cobalt(I1) ion is bound to singlet oxygen.



Experimental Section The cobalt(1I) complexes were prepared by previously reportedl3-I9 procedures and were characterized by means of elemental analyses, infrared spectra, and magnetic susceptibility determinations. Agreement with literature data was good. The cobalt-oxygen complexes were prepared by the methods of Floriani and CalderazzoZ0 for the unsubstituted salen compounds and Landels and RodleyI8 for [Co(bzacacen)]O2py. The purity of each sample was confirmed by repeated elemental analyses, infrared spectra, and magnetic susceptibility measurements. co(3CH10-saIdpt)O2 was obtained as a solid material by oxygenating

Journal of the American Chemical Society

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Co(3-CH3O-saldpt) in the same manner as that used by Floriani and Calderazzo20 to prepare Co(saldpt)02. The very dark brown solid material gave an elemental analysis consistent with the formulation as a 1:l adduct (calculated for C Z Z H ~ ~ N ~ OC,~ 54.10; CO: H, 5.57; N , 8.60. Found: C, 53.98, H, 5.57; N , 8.51), and exhibited a magnetic moment of 1.56 p g (22.5OC). The ESR spectrum of this material was also in agreement with the formulation as a superoxide.21 Cobalt( 111)-iodide complexes of the Schiff base compounds were prepared by treating the cobalt(I1) complexes with molecular iodine in CH2C12 solution. These complexes were also characterby means of elemental analyses, infrared spectra, and magnetic susceptibility determinations. XPS spectra were determined using an AEI ES-100 photoelectron spectrometer according to published procedure^.^^*^^ The previously described technique24 of mixing graphite with the sample to account for charging effects was used for the oxygen complexes, as well as the cobalt(II1) iodide compounds. The more thermally stable unoxygenated cobalt(I1) precursors were sublimed as thin films onto a gold-plated probe23 and the Au 4f5/2 and Au 4f7/2 levels were used for calibration of the spectrometer. XPS spectra were deconvoluted using the GASCAP IV25 program in conjunction with a PDP/8I computer. The program requires input for the number of peaks and the height, half-width, and position for each peak suspected of comprising the multiplet. Based on these parameters, a spectrum is calculated which can be compared to the experimental spectrum. The program contains a routine which performs a point-by-point subtraction of the calculated spectrum from the experimental spectrum. In all of the deconvoluted spectra presented in this paper such a subtraction was nearly a straight line, thus indicating a good fit between calculated and experimental spectra. All of the spectra to be discussed in the deconvolution section were deconvoluted at least twice (once each for two different runs of the same sample). Agreement between these two deconvolutions for all of the complexes was excellent.

Results and Discussion Effect of Coordination on the Ligand Donor Atoms. The donor atom (N and 0) 1 s 1 / ~binding energies for the free ligands are presented in Table I . These data were collected on samples which had been sublimed onto a gold-plated probe, except for H2(bzacacen), which was run as a 2:1 (sample to graphite) mixture on double-stick tape. For Hz(salen), H2(salophen), and Hl(saltm), the 0 I s l p binding energies are quite similar. By referring to structure I, it can be seen that the oxygen atoms in these three ligands are in approximately the same electronic environment; Le., all are phenolic oxygen atoms. Thus, the expectation that their binding energies should be similar is supported experimentally. The 0 1s,/2 binding energies in Hz(bae) and HZ(bza-

October 15, 1975

608 1 R

Table I. Nitrogen and Oxygen Core-Electron Binding Energies in Schiff Base Ligands (eV)a

R‘

Ia Y 0; R = CjH4; R‘ = R” = H b, Y 0; R = CIH,; R’ = H; R = C1 C, Y = 0 R = ClH4; R = OCH,; R” = H d, Y = 0 ; R = (CH,),NH(CH,),; R = R” H

HJsalen ) H25-CI-salen H23-CH,0-salen HL(ddpt)

e, Y = 0; R = (CH,),NH(CH,),; R = OCH,; R” = H f, Y = 0; R = C,H,; R = R” = H g, Y = NH; R = C,H,; R’ = R” = H

Hj3-CHg 0 d d p t Hdsalophen) Hi(oaben)

cacen) (structure 11) are also similar, but quite different R’

H-c\\

R’

0-c,

).-. C-N-

I

R -N-C

H

I I a R C?H4; R = R = CHj b, R = CiH,; R’ - C,H,; R = CH,

398.3 398.6 398.3 398.9 399.0 398.2

t t t t t

0.1 0.1 0.1 0.1 0.1 0.1

Nhj2

Complex Co(oaben)

398.2 i 0.1 (0.0) 398.9 t 0.2 (+0.6) 398.9 i 0.3 (+0.3) 399.1 f 0.1 (+0.2)

Co(bae) Co(bzacacen)

H H,(bae) (or Hdacacen) Hz(bzacacen)

(approximately 2 eV) from those of the ligands derived from salicylaldehyde. The oxygen atoms in Hz(bae) and Hz(bzacacen) are ketone oxygens and not phenolic oxygens. Thus, the conclusion of Dudek and Holmz6 that Schiff base ligands derived from P-diketones and diamines exist mainly in the ketamine form is supported by the XPS data. The donor atom core-electron binding energies have also been measured for the cobalt(I1) Schiff base complexes, and these are listed in Table 11. Positive binding energy shifts for nitrogen and negative shifts for oxygen are observed (relative to the free ligand) for the ligands derived from aryl aldehydes. A positive shift for nitrogen is consistent with a decrease in electron density on the nitrogen upon donation of its lone pair of electrons to the metal. A negative shift for oxygen can be rationalized on the grounds that two protons neutralize more of the electronic charge on the phenolic oxygen atom in the free ligand than a cobalt(I1) ion in the complex because of a higher charge density for the proton relative to the Co(I1) ion. In the Schiff base ligands derived from 6-diketones, the proton resides primarily on the imine nitrogen, not the oxygen, in the free ligand. Upon complexation, therefore, the electron density on the oxygen is reduced and the binding energy increases. It should be emphasized that the magnitude of the binding energy shifts may be considerably reduced over their real value because of the potential for hydrogen bonding between donor atom pairs in the free ligand. Effect of Ligands on the Cobalt Ion. In order to calculate chemical shifts for cobalt core (2p) electrons in the Schiff base complexes, the cobalt 2p binding energies in cobalt metal were determined. This was done by electroplating cobalt metal onto half of a rectangular piece of gold. Since the cobalt metal was in electrical contact with the conducting piece of gold, charging problems did not arise. However, it was necessary to argon ion etch the sample to remove any oxidized species from the surface. Replicate measurements on samples of cobalt metal cleaned in this manner showed that the C o 2p,/2 and 2~312binding energies are 793.0 f 0.1 and 778.0 f 0.1 eV, respectively. These values are tabu-

532.2 532.4 532.1 530.2 530.4

0.1 0.1 0.1 ?; 0.1 i 0.1 f t t

Table 11. Nitrogen and Oxygen Core-Electron Binding Energies in Co(I1) Schiff Base Complexes (eV)QVb

Co(sa1ophen)

‘R”

f

a Uncertainty corresponds to one standard deviation from the mean. Values less than 0.1 eV have been rounded off to 0.1 eV. ~ energy since These values represent a composite 0 1 s binding the oxygen peaks have not been deconvoluted.

Co (salen)

/R’

//C-H I

H,(salen) H,(salophen) H,(saltm) H,(bae) H,(bzacacen) H,(oaben)

CO(saidpt) .H,O

399.0

t

0.1

0 Is,/;

530.9 t 0.2 (-1.3) 531.2 i 0.1 (-1.2) 531.8 t 0.1 (+1.6) 530.9 t 0.1 (+OS) 530.8 i 0.1

0 Uncertainty corresponds to one standard deviation from the mean. b Binding energy shifts relative to the values for the free ligands. CThese values represent a composite 0 ls,,,binding energy. See Table VI11 for the deconvoluted values.

Table 111. Cobalt 2p Binding Energies for Cobalt Metal and Co(I1) Schiff Base Complexes (eV)a,b Compound Co metal Co(oaben) Co(sa1en) Co(sa1ophen) Co(bae)

Main c o 2P,/, 793.0 k 0.1 (794)C 794.2 t 0.2 (+1.2) 794.8 f 0.2 (+1.8) 794.9 t 0.2 (+1.9) 795.2 0.1 (+2.2)

c o 2P3jZ

796.2 i 0.3 (+3.2) 796.0 ?; 0.1 (+3.0) 796.1 i 0.2 (+3.1) 796.8 t 0.2 (+3.8)

778.0 t 0.1 (779)C 779.3 i 0.1 (+1.3) 779.9 i 0.1 (+ 1.9) 779.8 t 0.2 (f1.8) 780.1 f 0.1 (+2.1)

a Number in parentheses is chemical shift, where chemical shift = B.E. shift relative to Co metal. Uncertainty corresponds to one standard deviation from the mean of no fewer than four independent measurements. CValues reported in ref 41.

lated in Table 111, along with the cobalt 2p binding energies in some of the Co(I1) complexes. The Co 2p1p level is split into two peaks i n the complexes. An example of this splitting is shown in Figure 1 . The satellite structure is also present in the 2p3/2 level, but the main peak is considerably more intense than the satellite peak. This probably occurs because the process which causes the satellite structure is a secondary process. Consequently, the satellite peak would appear to be more important in the 2p1p level because the 2p1p peak is only onehalf as intense as the main photopeak arising from the 2p?/? level. The possibility of an Auger electron excitation as a source of the satellite peak can be either confirmed or ruled out by changing the energy of the incident radiation. By scanning a sample of Co(oaben) with the Mg K n X-ray ( E = 1253.6 eV) as the incident radiation, a spectrum showing satellite structure similar to that in Figure I was obtaincd.

Burness, Dillard. Taylor

/ PES Study of Co(Il)Schiff Base Complews

6082 Table N. Cobalt 2p,,* Binding Energies for Cobalt(I1) Schiff’ Base Complexesavb Compound Co (saldpt ).H 2O Co(3-CH30-saldpt) Co( 3-CH30-salen)

Co(5-C 1-salen) Co(bzacacen)

c o 2p312B.E. (eV)

Ligand type

780.8 t 0.1 (f2.8) 781.2 _c 0.1 (+3.2) 779.4 t 0.1 (+1.4) 779.4 t 0.1 (+1.4) 779.2 i 0.1 (+ 1.2)

Pentadentate Pentadentate Tetradentate Tetradentate Tetradentate

a Uncertainty corresponds to one standard deviation from the mean of no fewer than three independent measurements. b Number in parentheses is chemical shift relative to Co metal.

1 eV) than the shift for the unsubstituted Co(bae) complex.

I 801

797

793

Binding Energy (ev)

Figure 1. Splitting of the Co 2 ~ 1 1 2level in Co(oaben).

The satellite structure has been attributed to a multielectron excitation (“shake-up” or “shake-off”) process, whereby photoionization of the core (2p) electron causes simultaneous excitation or ionization of a valence electron. Satellite peaks in a large number of paramagnetic cobalt(I1) complexes have also been a t t r i b ~ t e d ~ to ’ , ~multielectron ~ excitation phenomena. The complexes in Table I11 are listed in the order of increasing binding energy, and the chemical shift is consistent with an increase in the oxidation number of cobalt from 0 to +2. More important, however, is the fact that the binding energy and thus the chemical shift appears to be dependent on the nature of the ligand. From visible spectral data,29-3’ the order of decreasing ligand field strength is given by oaben > salen 31 salophen > bae. Thus, in Co(oaben) the smallest chemical shift was observed because of greater charge donation to the metal by the ligand. On the other hand, bae is the weakest ligand of the series and thus Co(bae) exhibited the largest chemical shift. Since the ligand field strengths of salen and salophen are very similar, it would be expected that the cobalt binding energies in these Schiff base complexes would be similar. The data in Table 111 support this argument. It should be noted, however, that these data run counter to the “cis effect” series recently proposed32for these types of ligands. The cobalt 2~312binding energies for some additional Co(I1) Schiff base complexes are summarized in Table IV. These complexes are the Co(I1) precursors for the oxygen complexes. The effect of substitution on the sal or acac ligand system can be examined by comparing the binding energies of the complexes in Table IV with those of the unsubstituted compounds (Table 111). For example, the chemical shift for Co(3-CH30-salen) and Co(5-CI-salen) is 0.5 eV less than that for Co(sa1en). This is presumably due to the + M resonance (“electron donating”) effect of -OCH3 and -Cl.33 The importance of substitution on the ligand can also be seen in the case of Co(bzacacen). In this case, the Co 2p3/*chemical shift is considerably less (approximately Journal of the American Chemical Society

/

97:21

/

An examination of Table IV shows that the pentadentate ligands saldpt and 3-CH3O-saldpt produce higher Co 2~312 binding energies than any of the four-coordinate complexes listed in Tables I11 or IV. The secondary (dpt) nitrogen in these two complexes is coordinated to the metal and would be expected to increase the electron density on the metal by donation of the lone electron pair. This donation of electron density would result in a lower metal binding energy, not a higher one. The apparent contradiction can be explained by the fact that Co(saldpt).HzO and Co(3-CH30-saldpt) are high-spin complexes, whereas the four-coordinate materials are low spin.34 Because of metal-ligand electron-electron repulsion, the nucleus of the metal is more “shielded’ from some of the electron density of the ligand in the high-spin form than in the low-spin form. Consequently, the positive charge on the metal ion is not reduced as much as it would be if the complex were low spin, and the binding energies for the metal core electrons are higher. A determination of the metal binding energies in Cu(saldpt) affords an excellent test for the validity of this hypothesis. Since copper(I1) is a d9 ion, there is no possibility for the existence of highspin and low-spin forms. Thus, the additional nitrogen (dpt) atom should increase the electron density on the metal ion (relative to Cu(salen)) and result in a lower binding energy for copper core electrons. The Cu 2~312binding energies for Cu(sa1en) and Cu(saldpt) are 934.5 f 0.1 and 933.9 f 0.1 eV, r e s p e c t i ~ e l y Thus . ~ ~ the five-coordinate complex, in the absence of spin-state changes, exhibits a lower metal 2~312 binding energy than the four-coordinate complex. XPS Study of Cobalt-Oxygen Complexes. It was found that some dioxygen complexes could not be studied because they lost 0 2 under the vacuum conditions of the instrument. In fact, the Co 2~112and 2~312binding energies for [Co(salen)]202 were determined and found to be identical with those for Co(salen). An independent experiment showed that when the oxygenated sample was placed under a vacuum of approximately IOa6 Torr, the color changed from black to the maroon color of Co(salen). Similar experimentsdemonstrated that [Co(salen)]202(DMF)2 and [Co(3C H 3 O - ~ a l e n ] 2 0 2 ( H 2 0 ) 2also ~ ~ changed color and, thus, could not be studied under the high-vacuum (IO-’ to Torr) conditions in the instrument. All of the complexes whose binding energies are reported here, however, did not change color at Torr (at room temperature). The magnetic moments were also the same at both Torr and atmospheric pressure. The experimentally determined Co 2p3p and 0 1s1p binding energies for the dioxygen complexes are listed in Table V. For the tetradentate Schiff base complexes, the binding energy shift3’ is positive and ranges from 0.9 to 1.9

October 15, 1975

6083 eV. The positive increase in binding energy is consistent with an increase in oxidation state for the cobalt ion. It appears, therefore, that the increase in binding energy is consistent with the oxidative addition description of the oxygenation process. The binding energy increase accompanying the oxygenation process for the pentadentate Schiff base complexes is, within experimental error, equal to zero. At first the logical conclusion would seem to be that the Co(I1) ion is not oxidized during the formation of these oxygen adducts. However, it must be remembered that these two complexes are formed from high-spin precursors, and it has already been shown that the metal core-electron binding energies are dependent on the spin state of the metal ion. Thus, a direct comparison between binding energies of the high-spin precursor and the low-spin dioxygen complex is not meaningful or informative. The important point to note is that the [Co(saldpt)]02 and [Co(3-CH30saldpt)]Oz complexes yield Co 2~312binding energies which are in the same range as the other cobalt Schiff base oxygenation products. Furthermore, it should be noted that while the binding energy shifts are positive upon oxygenation, they are perhaps reduced somewhat because of the increase in coordination number accompanying oxygenation. Floriani and CalderazzoZ0 suggested that the Co( 11) complexes were more easily oxygenated in donor solvents because the coordinated solvent trans to the oxygen was able to compensate for the electronic charge which was transferred from cobalt to oxygen. Since the donation of negative charge to the cobalt ion by a ligand is equivalent to a reduction in binding energy for cobalt core electrons, it might be expected that complexes in which cobalt core electrons have lower binding energies would form more stable oxygen complexes. The data for Co(3-CH3O-salen) and Co(5-CI-salen) (Table IV) support this argument. The Co 2p3/2 binding energy is 0.5 eV lower in these two complexes than in Co(sa1en). Accordingly, the p-peroxo complexes, [CO(~-CH~O-S~I~~)]~O~(DMSO) and [Co(5-CI-salen)]~02(DMS0)2, are more stable with respect to loss of 0 2 under vacuum than [Co(salen)]202L2. The only previously reported XPS study of cobalt-dioxygen complexes has dealt with the binding energies of Co(bzacacen) and Co(bzacacen)O*py.’O Since the results of this study could have been complicated by a Co(II1) impurity (the Co 2p3/2 photoelectron peak for Co(bzacacen) was abnormally wide, -4.0 eV),’O we have determined the X P S spectra of these particular complexes again. In accord with the previously reported results, the Co 2~312peak of Co(bzacacen) (mixed in a sample to graphite ratio of 2:l and run on double-stick tape) was examined and a binding energy of 780.2 f 0.3 eV was obtained. The average fullwidth a t half-maximum ( F W H M ) for the peak was -3.8 eV. The large F W H M associated with the peak, as well as the large standard deviation, suggested that the compound might have been impure. The complex was purified by boiling the red-orange compound in ethanol and filtering the suspension while hot. The slightly yellow filtrate was discarded, and the red-orange crystals were dried in a vacuum desiccator. Sublimation of this compound onto a gold-plated copper probe gave a Co 2p3p binding energy of 779.2 eV, and the F W H M had decreased to 2.6 eV (a value typical of the other Co(I1) Schiff base complexes). In order to determine whether the purification treatment or the sublimation procedure was responsible for the removal of the impurity, the “purified” complex was mixed with graphite in a sample to graphite ratio of 2:l. The X P S spectrum of this material revealed a binding energy which was identical with that found by the sublimation procedure, and the F W H M was still 2.6 eV. From this information, it was concluded

Table V. Co 2p,, and 0 lsq, Binding Energies for Cobalt-Diosygen komplesesfeV)4b Complex [ Co(3-CH30-salen)]0,py

[Co(3-CH,O-salen)] ,O,(DMSO) [Co(S-Cl-salen)] ,O,(DMSO), /Co(bzacacen)10,py - -[Co(saldpt)] 0, [ Co(3-CH30-saldpt)] 0,

~-

c o 2P3!,

0 1s,/,c

781.3 f 0.1 (f1.9) 7 8 1.O f 0.1 (f1.6) 780.3 i 0.1 (+0.9) 780.8 i 0.1 (+1.6) (781.4 i: 0.l)d 781.0 i 0.1 (+0.2) 781.3 t 0.1 (+O. 1)

532.1 i 0.1 [ 3.6 1 532.0 t 0.1 13.61 531.2 i 0.2 [3.11 531.4 f 0.3 ~3.01 531.2 f 0.1 [231 532.0 t 0.1 13.91

a Number in parentheses is B.E. shift relative to unoxygenated Co(I1) complex. 21 Uncertainty corresponds to one standard deviation from the mean. =Number in brackets is average full-width at half-maximum (FWHM). These values represent a composite 0 1 sl,, binding energy. See Table IX for the deconvoluted values. d Value reported in ref 10.

785 78I 77 Binding E n e r g y (eV)

Co(Bzacace n) Figure 2. Solid-state decomposition of Co(bzacacen). i o = time of purifica tion.

that some type of impurity (in which the cobalt ion has a 2p3/2 binding energy of approximately 780 eV) was removed by the purification procedure. When the spectrum was taken 3 days later on the same mixture, the F W H M had increased to 3.6 eV. It was suspected that Co(bzacacen) was undergoing oxidation in the solid state without an accompanying color change.38 In order to confirm this suspicion, the X P S spectrum on the same mixture was taken again, almost 4 months after the purification procedure. The results of this time-dependent decomposition study are shown in Figure 2. The large shift to higher binding energy clearly indicated that solid-state decomposition has taken place in the complex. Although the decomposition product has not been identified, the spectrum suggests that oxidation to a Co(II1) species has taken place.

Burness, Dillard, Taylor

/ P E S Study of Co(IIj Schijf

Base Complexes

6084 Table VI. Co 2p,/,, 0 Is,, , and I 3dSl2Binding Energies in Iodocobalt(II1) Complexes teV)a-c

where B.E.S. is the binding energy shift relative to the appropriate Co(I1) compound. The result of this calculation for [Co(3-CH30-salen)]02py yields 86 f 17% for the exComplex c o 2P3h 0 h/,d I 3%, tent of electron transfer between cobalt and oxygen. The Co(3-CH30-salen)I(H,0) 781.3 i 0.1 532.7 i 0.1 619.7 i 0.1 large error is a result of the comparatively large uncertainty (+1.9) [2.5] [3.7] 12.41 ( f 0 . 2 eV) associated with each binding energy shift. SimiCo(3-CH30-salen)Ipy 781.6 I 0.1 532.5 ?: 0.1 618.9 i 0.2 lar calculations for the other oxygen adducts of the tetra(+2.2) 13.41 14.01 12.71 Co (5 -C1-salen)I i 8 i . i i 0.1’ 53i.9 t’0.1 619.8 i’0.1 dentate Schiff base complexes lead to the results summa(+1.8) [2.6] 12.9) [2.51 rized in Table VII. It is interesting to note that the per cent Co(bzacacen)I 781.9 i 0.2 532.5 i 0.2 619.7 f 0.2 electron transfer calculated is in reasonable agreement with (+2.7) [3.0] [2.9] r2.5 1 ESR ~ t u d i e s . ~ Co(saldpt)I.H,O 781.6 t 0.2 531.9 i 0.1 619.6 i 0.2 A calculation of this sort cannot be carried out with the (+0.8) 12.41 13.11 12.41 cobalt complexes of saldpt and 3-CH3O-saldpt because of Co( 3-CH30-saldpt)I 781.7 0.2 532.7 *-0.2 619.8 t 0.1 the spin state changes already discussed. However, an ex( + O S ) 12.51 14.21 12.31 amination of the absolute Co 2p3/2 binding energies in [Coa Number in parentheses is B.E. shift relative to Co(I1) precursor. (saldpt)J02 and [Co(3-CH30-saldpt)]02 can provide some b Number in brackets is average FWHM. CUncertainty corresponds insight as to whether the cobalt ion should be formulated as to one standard deviation from the mean. dThese values represent a composite 0 I s , binding energy since the oxygen peaks have Co(I1) or Co(II1). For example, the Co 2p3/2 binding enernot been deconvokted. gy range for the low-spin cobalt(I1) Schiff base complexes listed in Tables I11 and IV is 779.2-780.1 eV. Similarly, the C o 2p3/2 binding energy range for the iodocobalt(II1) comTable VII. Extent of Electron Transfer between Cobalt and plexes (Table VI) is 78 1.2-78 1.9 eV. The C o 2p3/2 binding Oxygen in Some Dioxygen Complexes energies for [Co(saldpt)]O2 and [Co(3-CH30-saldpt)]02 Extent of electron (781.0 and 781.3 eV, respectively) clearly fall in the bindComplex transfer from Co to 0 (%) ing energy range associated with cobalt(II1) complexes of [Co( 3-CH30-salen)]0,py 69-100 these Schiff base ligands. Although the calculations of per 65- 100‘ [Co(3CH30-salen)],O,(DMSO) cent electron transfer are crude and contain a sizeable un[ Co (5 -C1-salen) ] ,O ,(DM SO), 32-62’ certainty, the comparison of cobalt-oxygen complexes with [Co(bzacacen)] 0,py 47-71‘ the corresponding iodo complexes presents unambiguous evThese values are only estimates. Direct comparisons with the idence that the cobalt ion is oxidized during the oxygeniodo complexes are not possible because all of the ligands are not ation process. the same. See text. Deconvolution of Oxygen Peaks. The 0 1 s 1 p signal from the oxygen complexes was complicated by the presence of several different types of oxygen in the compounds. The XPS Study of Co(II1) Complexes. A series of cobalt(II1) complexity of the signal is evidenced by the large F W H M Schiff base complexes has also been investigated by XPS. associated with the 0 1 s l p peak (Table V). In order to sepThe reason for this study was twofold: (1) although a bindarate the individual peaks comprising the broad signal, the ing energy increase accompanied the oxygenation process, it oxygen peaks from the dioxygen complexes have been decould be argued that this was due to factors other than oxiconvoluted. It was felt that because of the inherent assumpdation of the cobalt atom-particularly electron withdrawal tions and approximations present in any deconvolution proby the dioxygen group; (2) a comparison between the oxycedure, a preliminary set of deconvolutions should be cargen complexes and the cobalt(II1) complexes will give an ried out to show not only that a broad peak could be deconestimate of the extent of electron transfer between cobalt voluted into several narrower peaks, but also that each of and oxygen. If it is assumed that electron transfer between the narrower peaks could be identified with a certain part of cobalt and iodine in the iodide complexes is loo%, i.e., the the complex under consideration. complex can be represented as Co3+-I-, then the Co 2~312 Assuming that the Schiff base oxygen donor atoms were binding energies in these complexes can be used to deternot changed significantly during the oxygenation process, mine whether the cobalt ion is, in fact, completely oxidized their binding energies in the Co(I1) complex and the dioxyduring the oxygenation process. The binding energies in gen complex should be quite similar. Thus, the first step in these complexes are presented in Table VI. A comparison of the deconvolution procedure was to determine the binding the Co 2 p 3 p binding energy shifts in Table VI with the Co energy of the oxygen atoms of the Schiff base ligand. Fig2p3/2 binding energy shifts for the corresponding oxygen ure 3 shows the deconvolution of the 0 ls1/2 peak from a complexes (Table V) shows that they are similar. The comsample of Co(salen) sublimed onto a gold-plated probe. The parison between the iodo complexes and the dioxygen com- agreement between experimental and calculated spectra is plexes is not a rigorous one because not all of the ligands very good (the baselines do not coincide because there is alwhich are present in the oxygen complexes are present in ways a finite number of “background” electrons a t a given the iodo complexes. The complex Co(3-CH3O-salen)Ipy, binding energy). The more intense peak, of course, correhowever, affords a direct comparison between the oxygen sponds to the phenolic oxygen atom of the Schiff base licomplex and the iodo complex because a pyridine ligand is gand. The peak to higher binding energy has been attribpresent in both. If the per cent electron transfer in the co- uted to contamination. The source of the contamination is balt(l1) compound is assigned a value of zero, and a value not known, but it arises in (or from) the instrument and is of 100 is assigned to the Co(Il1) iodo complex, then the per not an impurity in the sample. This was easily shown by decent electron transfer in the oxygen complexes can be calcu- convoluting another sample of Co(salen) run on a different lated by eq 1 day but under the same conditions as the sample whose spectrum is shown in Figure 3. The binding energies of the 0 1 s l p peaks in both deconvolutions were essentially the % electron transfer = same, even though the overall appearance of the two spectra B.E.S. for oxygen complex was quite different. This shows that the appearance of the x 100 (1) spectrum can be changed quite drastically simply by changB.E.S. for iodo complex ~

Journal of the American Chemical Society

/ 97:21 / October 15, 1975

6085

111

132

519

516

35

Bindin8 Energy (.VI

111

129

526

Bindini Energy (e")

Figure 3. Deconvolution of the 0 1s1/2 peak from Co(salen) sublimed onto a gold-plated probe: (A) comparison between experimental (-) and calculated .) peaks; (B) deconvoluted peaks which make up the calculated spectrum. (e

115

5 11

5 15

5 12

129

BindlnR Eorrgy t e c i

Figure 5. Deconvolution of the ~aien)]20~(DMSO mixed ) ~ with graphite and run on double-stick tape: (A) comparison between experimental (-) and calculated (. .) peaks; ( B ) deconvoluted peaks which make up the calculated spectrum.

.

529

Binding Energy ( e V 1

Figure 4. Deconvolution of the 0 1s1/2 peak from Co(bzacacen) mixed with graphite and run on double-stick tape: (A) comparison between peaks; ( B ) deconvoluted peaks experimental (-) and calculated which make up the calculated spectrum.

Figure 6. Deconvolution of the 0 Isl/2 peak from [Co(3-CH30salen)]102(DMSO) mixed with graphite and run on double-stick tape: (A) comparisons between experimental (-) and calculated (. . .) peaks; ( B ) deconvoluted peaks which make up the calculated spectrum.

ing the intensity of the 0 1s1/2 peak attributed to "contamination". Furthermore, the fact that the intensity ratio of the two peaks (i.e., Schiff base oxygen and "contamination" oxygen) does not remain constant rules out the possibility that the anomalous peak arises from an impurity in the sample. The probable source of this contamination is H20. For example, Carver et al.39have obtained 0 l s l p data for ZnO and Cr2O3, and attribute peaks at 533.2 (for ZnO) and 532.7 eV (for Cr2O3) to H20. To show that the deconvolution procedure is valid for samples which have been mixed with graphite as well as those which were sublimed, the 0 I s i p peak from a spectrum of Co(bzacacen) (freshly purified, mixed with graphite and run on double-stick tape) was deconvoluted (Figure 4). The deconvolution results show that no signal arising from the oxygen in the double-stick tape was observed, and that the contribution to the total signal by the oxygen in graphite was negligible. The binding energy values for the deconvoluted 0 1s1/2 peaks from Co(I1) Schiff base complexes have been summarized in Table VIII. The F W H M

Table VIII. Binding Energies of Deconvoluted 0 1sy2 Peaks from Co(I1) Schiff Base Complexes (eV)a

(e

-

e)

Oxygen type Complex

-OCH,

Co(sa1en) (1) (2) Co(3€H3O-salen) (1) (2) Co(bzacacen) a Number

532.3 [1.5] 532.5 Il.51 .

Contamination 533.0 12.41 j32.4 v.41 532.7 [2.4] 533.1 12.41 533.0 12.41 . .

Graphite

Schiff base 531.0 11.61 530.8 11.61 530.6 l1.51 530.7

531.8 [1.6]

11.51

530.6 11.6)

in brackets is FWHM.

associated with the Schiff base oxygen atoms is in good agreement with the value of 1.8 eV expected for the 0 I S I / I signal where there is only one type of oxygen.4o This fact,

Burness, Dillard, Taylor

PES Study of Co(II)Schiff Base Complexes

6086 Table IX. Binding Energies of Deconvoluted 0 1 s Peaks ~ from Cobalt(II1)-Dioxygen Complexes (eV)Q Oxygen typeb Complex [Co(S-Cl-salen)],O,(DMSO), Run no. 122373 Run no. 121473 [Co(3-CH30-salen)] ,O,(DMSO) [Co(bzacacen)] 0,py Run no. 123173A

a

b

C

533.1 12.41 533.3 12.41 533.3 12.41

531.8 11.91 531.9 P.11

530.8 11.91 531.0 [2.11 530.8 12.11

533.1 12.41 532.9 12.41 532.9 12.41 533.4 (2.41 533.0 12.41 533.4 12.41

531.8 12.11 531.9 11.91 531.8 12.01 531.8 12.11 531.8 11.91 531.9 (2.1 1

532.5

530.7 11.91 530.8 [2.11 530.6

532.1 11.91 532.3 I2.11 532.3

5 30.7 I2.11 530.7 11.91 5 30.6 I2.01 530.8 (2.11 5 30.5 11.91 530.7 12.11

531.4 12.11 Run no. 12874B 531.6 11.91 Run no. 12974 531.6 12.01 [Co(3-CH30-salen)]0,py 532.5 531.7 [2.11 12.11 [Co(saldpt)]0, 531.5 11.91 [ Co(3CH30-saldpt)] 0, 532.7 531.4 12.11 11.91 Number in brackets is FWHM. b Legend: a = “contamixtation” oxygen; b = graphite oxygen; c = Schiff base oxygen; d = -OCH, oxygen; e = p-peroxo oxygen; f = superoxo oxygen; g = DMSO oxygen. Q

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