FUNDAMENTAL ASPECTS OF PHOTOSENSITIZATION. INTERCOMBINATIONS IN MOLECULES

Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 TECHNICAL REPORT NO. 2 TO THE CHEMISTRY DIVISION OFFICE OF SCIENTIFIC RESEARCH U. S. AIR FORCE ? STAT STAT FUNDAMENTAL ASPECTS OF PHOTOSENSITIZATION. INTERCOMBINATIONS IN MOLECULES JUNE 15, 1958 STAT Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 4, Technical Report No. 2 to the Chemistry Division U. S. Air Force Office of Scientific Research STAT FUNDAMENTAL ASPECTS OF PHOTOSENSITIZATION. INTERCOMBINATIONS IN MOLECULES 4:4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 STAT Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Technical Report No. 2, to the U. S. Air Force Office of Scientific Research, Air Research and Development Command. June 15, 1958 STAT INTERCOMBINATIONS FUNDAMENTAL ASPECTS OF PHOTOSENSITIZATION. IN MOLECULES. Table of Contents 1. Solvent Effects in Merocyanine Spectra, E. G. McRae STAT (SPectrochimica Acta).* 2. Intramolecular Twisting Effects in Substituted Benzenes. I. Electronic Spectra, Eion G. McRae and Lionel Goodman. (J. Molecular Spectroscopy). 3. Intramolecular Twisting Effects in Substituted Benzenes. II.. Ground State Properties. (I. ,Chemical Physics).* if. Energy Transfer in Molecular Complexes of Sym-Trinitrobenzene with Polyacenes. I. General Considerations, S. P. McGlynn and J. D. Boggus. (J. American Chemical Society),* STAT Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R0071onn4nnno_a Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? 1,2 SOLVENT EFFECTS ON MEROCYANINE SPECTRA by.E. G. McRae3 Department of Chemistry, University of Western Australia, Nedlands, Western Australia, and Department of Chemistry, Florida State University, Tallahassee, Florida. (1) Taken in part from a thesis submitted by E.-G. McRae for the degree of M. Sc. at the University of Western Australia. (2) Part of the work was carried out under a contract between the U. S. Air Force, Office of Scientific Research, ARDC, and the Florida State University. (3) Present address: Department of Chemistry, Indiana University, Bloomington, Indiana. (Abstract) Solvent effects on the visible absorption spectra of three merocyanine dyes are described. The dyes comprise two (I and II) of exceedingly high polarity, and a third (III) less polar than I and II but still highly polar by ordinary standards. / I. H3CN/:)= 0.. 0-0 / 1 II. 3H ctsn=cH-en=c14-cw --:.c.\ N.?..1 C ' 5 \ = C-14 de4 ? Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -2- The absorption curves, values of the extinction coefficient and frequency at the absorption maxima ( C max and), max respectively) and oscillator strengths are given for I dissolved in pure solvents, and for dyes II and III in a variety of both pure and mixed solvents. For each dye, 6 max and 1) max undergo pro- nounced solvent effects, but the oscillator strengths are in- sensitive to solvent perturbations. The results are discussed in terms of a simple theory in which the combining states are considered as superpositions of a polar and a non-polar resonance structure. A more detailed theory is applied in the interpre- tation of the frequency shifts induced by non-hydrogen bonding solvents. I. INTRODUCTION The visible absorption spectra of highly polar merocyanine dyes undergo extraordinary solvent effects. The phenomena were first reported by Brooker and his collaborators,45 who studied (4) L.G.S. Brooker, G. H. Keyes, R. H. Sprague, R. H. Van Dyke, E. Van Lare, G. Van Zandt, F. L. White, H.W.J. Crepsman and S. G. Dent, J. Am. Chem. Soc., 5332 (1951). (5) L.G.S. Brooker, G. H. Keyes and D. W. Heseltine, J. Am. Chem. Soc., 2, 5350 (1951). the spectra ofl several merocyanines dissolved in pyridine - water mixed solvents. It was found that variation of the percentage water content of the solvent gives rise to pronounced changes of both the maximum extinction coefficients, e max' and the corre- sponding frequencies, 11 max' at the visible absorption maxima. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-0104riRnn9-4nnnAnnno Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -3- The main qualitative features of the solvent effects have been described in a recent review' by Brooker.6 For an (6) L. G. S. Brooker, Experientia Supplementum II (XIV the International Congress of Pure and Applied Chemistry), 229 (1955). exceedingly highly polar dye in a pyridine - water or lutidine - water mixed solvent, the progressive addition of water to the solvent leads to a shift of 1) max to higher frequencies, with a concomitant diminution of 6 max. The curve of C maxml.), max has the shape of the "highly polar" branch of the curve shown in Fig. 1. The arrow indicates the effect of adding water to the solvent. The opposite behavior is exhibited in the case of a dye which is comparatively weakly polar (but Which may still be fairly highly polar by ordinary standards). Here, the plot of C max vs* I/ max resembleS the "weakly polar" branch (Fig. 1). For dyes of intermediate polarity, the initial addition of water to a pure pyridine or lutidine solvent has an effect qualitatively similar to that observed with weakly polar dyes. Upon further progressive addition of water to the solvent, C max and max pass through extreme values, and the subsequent differential solvent effect is qualitatively Similar to that observed with exceedingly highly polar dyes. For convenience in a. subsequent discussion, we shall refer to points on the C max X' max max plot as "solvent representative points" for the dye in question. The point on the ,plot at which C max attains its maximum value will be called the "reversal point", and will be thought of as the junction of the two branches.7 Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043Rnn9?Innn4nnno a Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -4- (7) Fig. 1 is slightly idealized in that the minimum of .1,/ max is shown to coincide with the reversal point. Actually, the two extremes do not exactly coincide, although in most but not all cases they lie quite close together. With this nomenclature, the above description of merocyanine solvent effects may be summarized as follows: for exceedingly highly polar dyes, the representative points for pyridine - water or lutidine - water solvents lie on the highly polar branch, for relatively weakly polar dyes they lie on the weakly polar branch, and for dyes of intermediate polarity they straddle the reversal point. The work reviewed by Brooker6 is extensive in that it en- compasses the spectra of dyes covering a wide range of polarity. However, the published data pertain only to the absorption maxima, and the solvents used were limited largely to pyridine - water and lutidine - water mixtures. In this paper, we give a more detailed description of solvent effects on the visible absorption spectra of three of the merocyanines previously studied by Brooker et Al.4'5 Of the three dyes, I and II, which have the same pair of end-groups, are exceedingly highly polarl while III has intermediate polarity.8 The absorption curves of II (8) I and II are labeled XII (n = 1 and n = 2 respectively) in ref. 4, and III is labeled V in ref. 5. In pure solvents have been given by Bayliss and McRae, in ?. preliminary report on the present work.9 (9) N. S. Bayliss and E. G. McRae, J. Am. Cheri. Soc., 21?, 5803 (1952)... Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R00230004nnnq_a Declassified in Part - Sanitized Cop Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ii fl.ge. III -5- 0 /C-0 C14 -CH C C14- OW= Ci1-C14 *2= s\C. = CH = e 143 Taken together with the data previously published by Brooker et al,45 our results provide an overall picture of solvent effects on merocyanine band frequencies, intensities (oscillator strengths) and band shapes. This information is thought to be of particular interest in view of several recent discussions, of the origins of solvent effects on merocyanine spectra.69/10-12 (10) W. T. Simpson, J. Am. Chem. Soc., 21, 5359 (1951). (11) J. R. Platt, J. Chem. Phys., gl, so (1956). (12) E. G. McRae, J. Phys. Chem., 61, 562 (1957). Declassified in Part - Sanitized Cop Approved for Release ? 50-Yr 2013/09/13 : CIA-RDP81-01043R00230ouonng_q Declassified in Part - Sanitized Copy Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -6- II. EXPERIMENTAL. Solvents: - Most of the solvents used in this work have been described in a previous paper,13 and the remaining solvents (13) N. S. Bayliss and E. G. McRae, J. Phys. Chem., 1130 1006 (1954). are described below. Except where other references are given, the physical constants in parentheses are those quoted by Timmermans.114. (14) J. Timmermans, "Physico-chemical Constants of Pure Organic Compounds", Elsevier Publishing Co., Amsterdam, 1950. Aniline of a technical grade was dissolved in hydrochloric acid, and the main impurity, nitrobenzene, was removed by steam distillation. The aniline hydrochloride was neutralized, and steam distilled. The distillate was dried with potassium hydroxide, and fractionated twice under reduced pressure. It was stored in the dark over potassium hydroxide pellets, and fractionated again immediately before use. B. P. 94?C/35MM. (94/35)15; 111)20 1.5860 (1.5863). (15) Landolt-Bornstein, "Physikalisch-Chemische Tabellan", 5th Ed., Eg. III C, Springer, Berlin, 1935, p. 2462. Dioxane of British Drug Houses Technical grade was refluxed for ten hours with 1/10 its volume of 0.1N hydrochloric acid. It was then allowed to stand for one day over scdium hydroxide sticks, and fractionated. It was kept in the dark and used within one week of purification. B. P. 101.6?C (101.4); LID20 1.4215 (1.4214). Declassified in Part- Sanitized Co.y Approved for Release 50-Yr 2013/09/13: Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -7- Formamide was prepared from ethyl formate by the method of Slobodin et al,16 and the product was fractionated under (16) Ya. M. Slobodin, M. S. Zigel and M. V. Yanishevska, J. Applied Chem. (U.S.S.R.) 16, 280 (1943). See Chem. Abstr. 32, 702 (1945). reduced pressure. The formamide was again fractionated immedi- ; np ately before use. B. P. 116?C/39.2 mm. 2/3 1.4482 (1.4475). Pyridine of a grade conforming to British Drug Houses Analar standards (Judex analytical reagent) was allowed to stand for one week over sodium hydroxide sticks, refluxed for ten hours over freshly burned calcium oxide, and fractionated. B. E. 115.2?6 (115)4); 418. 7 1.5106 (1.5106). Buffer solutions: For the a range 5.0 - 8.0, McIlvaine's standard buffer solutions17 were prepared, using Analar grade (17) "Handbook of Chemistry and Physics", 24th Ed., Chemical Rubber Publishing Co., 1940, p. 1374. reagents. The solvent of Eli 9 was a 0.05 molar solution of Analar grade borax. Merocyanine Dyes: Pure merocyanine dye samples were supplied by Dr. L. G. S. Brooker, Solutions: In so far as permitted by the dye solubill.ties, the dye solutions were prepared to give a minimum transmission reading between 20 and 70%. This corresponds to a dye concen- tration in the vicinity of 5 x 10-6M. Where practicable, solutions of known dye concentration were prepared. Weighed 1 mg. dye samples were dissolved, and the resulting solutions diluted either by volume or by weight. The latter method was Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 0 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -8- ' used for most of the solutions in mixed solvents. Volume di- lutions were carried out with a standardized 5 ml. pipette and standardized 25 ml. flasks. Where weight dilution was employed, the dye molarity was calculated with the aid of the tabulated densities of the mixed solvents in question.18 (18) Landolt-Bornstein, "Physikalisch-Chemische Tabellen", 5th ed., Springer, Berlin, 1935. Spectra': Except in the tests of Beer's law (see below), all spectra were measured with a Beckman spectrophotometer, model DU, using matched 1 cm. Corex cells. Frequencies, V (cm-1), were obtained from the wavelength settings, no vacuum corrections being applied. The molar ex- tinction coefficients, E were calculated according to the formula: E (1/ed) Ian (100/Z), where c denotes the molarity, d the path length in cm., and T the percentage transmission reading. Oscillator strengths, f, were calculated from the absorption curves according to the formula19 (19) R. S. Mulliken and C. A. Rieke, Rep. Prog. Physics 8, 231 (1941). f = 4.32 x 10-9 fE di/ Errors: The errors in the determination of V ranged max from 20 to 50 cm-1, depending on the band width. The errors in the measurement of absolute extinction co- efficients, which were essentially concentration errors, did Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -9- not exceed 5%. In several cases it was not possible to measure extinction coefficients, because of sparing dye solubility. In these cases, E max was estimated by adjusting the area under the absorption curve to correspond to the oscillator strength of the dye dissolved in water. The justification of the procedure rests on a particular result of the present work, namely that the oscillator strengths are rather insensitive to solvent per- turbations. The percentage error of E max determined in this way is considered not greater than the total percentage variation of oscillator strength, viz. 20% (Sec. III). In merocyanine spectra, the visible absorption band is not overlapped appreciably by bands at higher frequencies; conse- quently the same errors in the oscillator strengths were only slightly greater than those in the extinction coefficients. In a few cases, which are noted individually in the next section, the errors were probably greater than indicated above. In the cases in which a comparison is possible, our results agreed with those of Brooker et L1,4$5 within the limits of error quoted above. Tests of Beer's Law: Beer's law tests were carried out using a Beckman spectrophotometer, model DK, with 0.1, 2.0 and 10.00 cm. cells. The spectra of dyes I and III were measured in the concentration range 3 x 10to 3 x 10-5M. Most of the measurements were carried out at concentrations near the middle of this range (iv 5 x 10-6M). The solvents in each case were pyridine - water mixtures. The solvent for dye I contained 90 mole % pyridine, and that for dye III, 80 mole % pyridine. In Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13 : CIA-RDP81-01043R002300040009-9 -10- both cases, Beer's law was obeyed well within the dilution error, and there was no detectable change of band shape throughout the hundred-fold range of concentration. III. RESULTS. The solvents used in this research are listed in Table 1, together with their designations in the figures, their relevant physical properties, and the values of some derived properties thought to be of importance in the interpretation of the solvent effects (Sec. IV). Dyes I and II: The results Obtained with dyes I and II dis- solved in pure solvents (Table 2, Figs. 2,3) are qualitatively similar, the solvent effects being somewhat less pronounced in the case of I. In the case of dye II, the results include the effects of mixed as well as pure solvents (Table 3, Fig. 4). The absorption bands of dyes I and II in 0.26N hydrochloric acid lie at higher frequencies than the corresponding curves for water solvent. The absorption curves obtained at lower acid concentration passed through a well-defined isosbestic point, Indicating that the higher-frequency absorption is due to the protonated dye in each case. Freauencies: The pure solvents induce increasing shifts to higher frequencies in the order: dioxane, chloroform, nitrobenzene pyridine, acetone, aniline, ethanol, formamide, water. As has been pointed out previously,9 there is a sharp distinction between the effects of the hydrogen bonding solvents (last four Declassified in Part - Sanitized Copy Approved for Release @ SO -Yr 201 .c - Declassified in Pad- Sanitized Cop Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -11- members of the above sequence) and the non-hydrogen bonding 20 solvents (first five members). (20 It is not clear whether or not. chloroform should be classified as a hydrogen bonding solvent. Presumably it can form hydrogen bonds with the dyes, yet its solvent effect is intermediate be- tween those of dioxane and pyridine. A similar result appeared . in the writer's analysis of solvent effects on the spectrum of phenol blue;12 there, it was found that the frequency shift pro- duced by chloroform was close to that Predicted for a non- hydrogen bonding Solvent having the same macroscopic properties. In this paperl chloroform will be considered provisionally as a non-hydrogen bonding solvent. In each case, the absorption of the protonated dye lies at a higher frequency than that of the dye itself dissolved in water. Intensities: The band intensities do not undergo pronounced solvent effects, nor do they show any progressive variation with the band frequency. Yet, for each dye, some of the observed oscillator strengths differ significantly from the mean observed oscillator strength. For example, acetone, and to a smaller extent, pyridine, appear to cause a relative intensification. It is noteworthy that the intensity of absorption of the proto- nated dye is nearly the same as that of the dye itself dissolved in water. Band Shapes: The absorption curves for dyes I and II in dioxane each display a definite shoulder on the high-frequency side. In the case of dye II, further. structure may be discerned at still higher frequencies. With dye II, the vibrational structure is developed even more strongly in benzene-rich- benzene-acetone and benzene-pyridine mixed solvents, a second Declassified in Part - Sanitized Cop Approved for Release 50-Yr 2013/09/13 ? CIA RnPRi_ni na Dr-vvy)t-v-InArsr,, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -12- peak appearing in each case. The separation of the peaks is 1030 ? 100 cm-1.21 (21) The absorption curves obtained with benzene-rich mixed sol- vents changed slowly with time, probably because of the dye crystallizing out. They are less accurate than the other curves, but the frequencies were reproducible within the quoted limits of error. The structureless absorption curves become progressively broader with increasing shift to higher frequencies. On plotting the corresponding solvent representative points for dye II, it is found that within the limits of error in the determination of En , they all lie close to a curve corresponding to the highly polar branch. (Fig. 5. The values of E for dioxane-water max solvents were determined on the assumption of a constant os- cillator strength. The actual values may be as much as 20% higher). It is interesting that the point for the protonated dye lies near the extrapolated curve. The representative points corresponding to the absorption curves with structure lie close to a curve corresponding to the weakly polar branch, between the reversal point and the minimum of )) max* Dye III: At first sight the absorption curves for dye III in pure solvents (Table 2, Fig. 6) appear to bear no relation to those obtained with dyes I and II. However, the results are readily rationalized with reference to the absorption curves obtained with mixed solvents (Table 4, Fig. 7), and the C. max vs? 1) max plot showing points for both pure and mixed solvents (Fig. 8). Again, the solvent representative points all lie close to a curve having the general shape of that shown in Fig. 1. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDPRi-ninaqpnno ruin Ann', Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -13- The visible absorption of dye III in water is the super- position of the absorption of the dye itself and a higher- frequency absorption attributed to the protonated dye. The ab- sorption curves for the separate components (Fig. 6) were obtained in. buffer solutions of pH 9 and pH 6 respectively. At intermediate EU, the composite absorption curves were found to pass through a definite isosbestic point. A similar result was obtained with the solvent ethanol, in which the composite ab- sorption curve varied slowly with time. By observing the ab- sorption over a period of a few hours, it was resolved into the two curves shown in Fig. 6, the higher-frequency absorption being attributed to the protonated dye. The curves obtained with ethanol solvent are somewhat less accurate than the other curves shown in Fig. 6. The absorption observed with the solvent formamide Is thought to be due to the protonated dye. Freauencies: Of the pure solvents, ethanol has a repre- sentative point closest to the reversal point. The representa- tive point for water definitely lies on the highly polar branch of the C max ma. 11max curve, while the points for the non- hydrogen bonding solvents all appear to belong to the weakly polar branch. However, on the weakly polar branch the solvent order of increasing shift to higher frequencies is not the reverse of that observed with dyes I and II, as would be expected if there were a perfectly regular relationship between Emax and )) max' ,The consideration of band frequencies alone affords no definite distinction between the effects of hydrogen bonding ? Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 : CIA-RnpRi_nirm-/onnnn ^^,A Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -14- and non-hydrogen bonding solvents. Perhaps the most concise description of the effect of hydrogen bonding, in terms of ex- perimentally observed quantities, is that it causes a displace- ment of the solvent representative point in the arrow direction along the 6 max max curve (Fig. 1). This does not 22. 11 necessarily imply a large frequency shift. Intensities: Again, the band intensities appear to be rather insensitive to solvent perturbations, although the vari- ation of oscillator strength from solvent to solvent slightly exceeds the experimental error in a few cases. Band Shapes: The absorption curves correspondong to repre- sentative points lying on the weakly polar branch display defi- nite vibrational structure. A high-frequency shoulder or second peak is observed in every case, together with some less pronounced structure at still higher frequencies. As the sol- vent representative point moves away from the reversal point, the second peak grows up at the expense of the first, actually surpassing It in intensity in the case of a benzene-pyridine solvent.21 (Throughout, C max and )) max refer to the lower- frequency peak). The separation of the peaks is 1100 100 cm-1 (average of observed separations). On the high-frequency side of the reversal point, the ab- sorption curves undergo progressive broadening similar to that observed with dyes I and II. The trend extends to the absorption curves of.the protonated dye, the corresponding points lying near the extrapolated E max max curve (Fig. 8). Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -15- Gross Features of the Solvent Effects: Inasmuch as the dyes I-Ill are typical members of the series of dyes studied by Brooker et al,/5 the gross features of the solvent effects reported here are probably common to all merocyanine spectra. They are as follows: (1) For a given dye, all solvent representative points lie near part of a curve having the general shape shown in Fig. 1. The particular part of the curve traced out by the points for a given series of solvents depends on the dye polarity, as indicated in Sec. I. (2) The representative points for hydrogen bonding sol- vents tend to be displaced in the arrow direction along the E. max max curve (Fig. 1), compared with non-hydrogen bonding solvents. (3) Band intensities (oscillator strengths) are almost independent of the solvent. (4) As the solvent representative point moves away from the reversal point on the weakly polar branch, at least one new absorption peak grows up on the high-frequency side, at the ex- pense of the lowest-frequency peak. The peak separation is 1000-1100 cm-1. IV. DISCUSSION Frequency Shifts: The gross features of the frequency shifts have been explained by Brooker6 in terms of the relative solvent stabilization of the extreme polar and the non-polar Declassified in Part - Sanitized Copy Approved for Release c 50-Yr 2013/09/13: CIA-RDP81-01043R00230004nnnq_a Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 resonance structures. structures. (IVa and IVb respectively). ? + I (a) IV , ? N?(c=c?) (b) Brooker has identified the reversal point with the isoenergetic point, i.e., the point at which the two structures have the same energy. The situation in which the polar structure is the more stable corresponds to the highly polar branch of the E max vs. y curve, and the opposite situation corresponds to the weakly polar branch. Brooker's interpretation has been elaborated by Simpson,10 who has taken into account the interactions between many resonance structure functions. However, the results of Simpson's treatment are not in agreement with experiment,9 and the treat- ment itself has been adversely criticized on the ground that it is based on an aver-simplified representation of the solvent- solute22 interaction energy. Platt11 has pointed out the (22) Y. Ooshika, J. Phys. Soc. Japan, .24. 594 (1954). relationship between Brooker's interpretation and an'alternative scheme in which the frequency shift is related to the relative magnitudes of the dipole moment of the solute in its ground and excited states.23 (23) Platt has attributed the latter method of interpretation to McConne1124 and to Bayliss and McRae 27 Actually, Platt's dis- cussion represents an advance on the earlier work, which was based implicitly on the assumption of a rigid solute dipole. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13 ? CIA-RDP81 nin4npnn9qnnnAnnr,r, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 4t, -17- (24) H. McConnell, J. Chem. Phys., 20, 700 (1952). (25) N. S. Bayliss and E. G. McRae, J. Phys. Chem., 2, 1002 (1954). Recently, the writer12 has given a general treatment of frequency shifts arising from dipole interactions. It was shown that the frequency shift may be expressed in terms of contri- butions to the environmental electric field at the solute dipole (all molecular dipoles being treated as point dipoles). In the case of a merocyanine dye dissolved in a polar solvent, it was . proposed that as far as the relative frequency shifts induced by different solvents are concerned, the most important contribution to the environmental field is the field arising from the oriented permanent dipoles of the solvent molecules. Denoting the latter field by R, and neglecting all other contributions to the en- vironmental field, the following expression was derived for the frequency shift: Vrer = (1/ 11- 9-) (Zz-Ze) ? R r (3/2 h c) (01 - c ) R2 (1) I e Here, and 1) ref denote the band frequencies for the dye dis- solved respectively in the solvent under consideration, and in a non-polar reference solvent. On the right, h and c.have the usual meanings, M and 0( respectively signify the permanent dipole moment and isotropic polarizability of the isolated solute molecule in its ground electronic state, and Me,o,(e stand for _ ? the corresponding quantities for the excited state. The term Involving R2 represents the quadratic Stark effect. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 : CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized CO .y Approved for Release ? 50-Yr 2013/09/13 : CIA-RDp81-01043R002300040009-9 -.18- It has been shown that with0C oie and M assumed .g. -e parallel to ma, Eq. 1 provides a satisfactory interpretation of the gross features of the frequency shifts in merocyanine spectra, including the order of magnitude of the shifts.12 From a purely qualitative viewpoint, the description is exactly the same as that given previously by Platt.11 The important new feature of the approach based on (1) is the introduction of the field ,intensity, RI as a parameter to which the frequency shifts may advantageously be referred. Probably the most serious errors inherent in (1) are those incurred through the neglect of environmental field contribu- tions other than R. This implies the neglect of dispersive interactions and interactions of the solute permanent dipole- solvent induced dipole type. In most cases apart from mero- cyanine spectra, these interactions make an important if not dominant contribution to the frequency shift. However, they may be expected to play a relatively small part in the case of mero- cyanine spectra, because of the high polarity of the merocyanines compared with ordinary molecules. The extent to which this expectation is realized is indicated in the following discussion of the results of the present work; this discussion is based at first on Eq. 1. Non-hydrogen Bonding Solvents: In the absence of hydrogen bonding, the field intensity may be related to macroscopic properties of the solvent. On the basis of the simplest possible model for the solute in solution (point dipole at the center of a spherical cavity in a homogeneous dielectric medium), together Declassified in Part - Sanitized Copy Approved for Release 50 -Yr 0 ID Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -19- with certain other simplifying assumptions, there results12 2 M [D - 1 ... no2 - 1 (2) a3 D "4-2 n02 t. 2J where a denotes the cavity radium, D the solvent dielectric constant and no the refractive index of the solvent at zero frequency. COmbining (1) and (2), assuming Me parallel to ML in (1) and denoting the expression in brackets (Eq. 2) by F (9 -D n0 )9 we obtain: - ML OIL - F I- (6/ h a6)M ref = (2/ )1 a3) c_ ) F2 (3) _ According to (3), the band frequencies should vary regularly, though not necessarily linearly, with F. Figs. 9 and 10 show graphically the relationship between F and the observed band frequencies for dyes II and III dissolved in non-hydrogen bonding solvents. The corresponding plot for dye I is similar to that for dye II. The values of F for the pure solvents are taken from Table 1 (here and elsewhere in this paper, all refractive indices are replaced by LID for the purpose of numerical calculation). For the benzene-pyridine mixed solvents, the dielectric constants are interpolated from the data of Lange.26 It is seen that there is a definite though (26) L. Lange, Z. Physik 2a, 169 (1925). imperfect correlation between the frequency shifts and the corre- sponding values of F. The points obtained for dye II lie near Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R0021onunnma Declassified in Part - Sanitized Co .y Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? -20- a curve having the shape expected from (1) and (2), with M M and 0( )0( . Z. The irregularities in the relationship between band fre- quency and solvent F may be discussed in terms of the super- posed effects of dispersive interactions and of interactions of the dipole-induced dipole type; as noted above, both types of interaction were neglected in the derivation of (1). Dispersive interactions invariably give rise to a shift to lower frequencies, relative to the vapor frequency (the "general red shift"). The general red shift is expected to be particularly large for strong bands such as appear in the visible spectra of dyes, and the relative magnitudes of the red shifts produced by different solvents are known to depend primarily on the solvent refractive index.12,22,26,27 (27) The general red shift was called the "polarization red shift" in ref. 25. Dipole-induced dipole interactions are expected to produce a shift to lower frequencies relative to the vapor frequency if the solute dipole moment of the dissolved dye molecule is greater in the excited state than in the ground state; other- wise, a shift to higher frequencies is expected. For a particu- lar solute, the magnitudes of the shifts induced by different solvents are expected to depend on the solvent refractive index. 12,22,25 Accepting the above description of the dispersive and dipole-induced dipole effects, we conclude that the dipole- induced dipole shift augments the general red shift in the case Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R00230ounnmq Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? -21- of dye III and opposes it in the case of dye II. Upon ref- erence to Figs. 9 and 10, we find that the most noticeable irregularities occur with dye III in nitrobenzene and acetone. Now these two solvents have respectively the highest and the lowest refractive indices of the series. By virtue of the superposed effects of dispersive and dipole-induced dipole interactions, the two solvents are expected respectively to pro- duce larger and smaller red shifts, compared with a reference solvent of intermediate refractive index, than predicted on the basis of the solvent F alone. The corresponding irregular- ities in the case of dye II in nitrobenzene and acetone are much less pronounced, as is expected in view of the partial cancellation of the dispersive and dipole-induced dipole shifts. A similar explanation can be advanced for most of the remaining irregularities; however, it is most likely that those irregu- larities reflect the limitations of the simple theory in which the solvent is treated as a homogeneous dielectric medium. It is readily shown that the above discussion involves quantities of the correct order of magnitude. The curves super- posed on Figs. 9 and 10 represent the behavior predicted by (3), with M x: 10 Debye, a = 42, and c< = 0.1+ x 10-23 cm3 for each of the two dyes, M - M = 0.05 Debye for dye II and 7e- M M = -1.7 Debye for dye III. It may be noticed that the curves are drawn on the assumption that the value of (04E 11is the same for both dyes; this is to be expected in view of the general similarity of the spectra of the two dyes. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -22- It is noteworthy that the difference between the ground and excited state polarizabilities need not be particularly large to account for the observed trends. The chosen value of the difference is about one-quarter of the contribution of a strong visible transition to the ground state polarizability. For strong transitions, such as those considered here, the general red shift is given approximately by12 -14 Lf ,J0 (dispersive) -2.14 x 10 - 1 2n2 t- 1 where L and n respectively denote the "weighted mean wavelength" and refractive index of the solvent at the band frequency, f denotes the oscillator strength of the transition in question, and a again denotes the cavity radius. The minus sign indi- cates that the shift is to lower frequencies, relative to the vapor frequency. Adopting L = 1250 A, 4 i and f 0.8, we obtain 2 - nb ? 4 ?,(dispersive) go 3390 (4) 2nt 4- 1 as - rough estimate (cm-1) of the general red shift. The literal application of the above formula (refractive indices from Table 1) accounts for a little over half the frequency separation of the points on Fig. 10 for dye III in nitrobenzene and acetone. According to a formula given previously,12 the dipole- induced dipole shift, relative to the vapor frequency, is Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R0021onunnma Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -23- given by .8.0 (dipole-induced dipole) = 2 2 2 - 1 4 - /6 no hca32n02 r 1 Actually, the above formula does not apply accurately to the merocyanines, because it is based on the assumption of a rigid solute dipole. In a more elaborate discussion, we would have to replace M and M by appropriate expressions for the dipole -e moments of the dissolved dye. Bearing that in mind, the above formula suffices to show that if, for the dissolved dye, the ground and excited state dipole moments differ by less than 2 Debye, then the magnitude of the dipole-induced dipole shift is approximately equal to or less than that of the general red shift. We have shown, first, that the observed frequency shifts display a definite though imperfect correlation with the sol- vent F, which has been defined with a reference to Eq. 2; second, that the observed behavior conforms approximately to that predicted by (3), with plausible values for the dipole moments and polarizabilities of the dyes; third, that the most noticeable discrepancies which do occur are of the nature and approximate magnitude to be expected from the superposition of dispersive and dipole-induced dipole effects. The evidence leaves little cause to doubt that the frequency shifts are caused primarily by dipole-dipole interactions, with the quad- ratic Stark effect playing an important or dominant role. Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Hydrogen Bonding Solvents: Although the order in which the hydrogen bonding solvents induce shifts to higher fre- quencies is the same as that of increasing F, it is clear from the magnitudes of the shifts that they correspond, in a formal sense, to values of R much larger than those calculated from (2). It appears that the quadratic Stark effect makes a dominant contribution to the frequency shift. Even when the quadratic Stark effect has been taken into account, there seems to be no simple explanation of the results in terms of hydrogen bonding. To take an extreme example, in the spectrum of dye II, the solvent water induces a shift of about 4500 cm-1 to higher frequencies, referred to acetone. If we allow 500 cm-1 for the change of Ft there remains 4000 cm-1 or about 12 Kcal/mole, to be accounted for by hydrogen bonding. This appears to be too large a shift to be attributable to the formation of a single hydrogen bond. Again the case of dye II the shift induced by water is about twice as great as that induced by formamide, and about four times as great as that ? induced by ethanol (all referred to acetone), though the three solvents presumably form hydrogen bonds of about the same strength. On the other hand, the band frequencies for dye II in ethanol and aniline exceed by about the same amount (^'1200 cm-1) those expected on the basis of the solvent F alone. We suggest that in the case of the solvent water, and possibly formamide, two or more solvent molecules simultaneously form strong hydrogen bonds with one dye molecule to form a com- plex of structure V. In each of the dyes 1-III only one dye Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01041Rnn9-4nnnannna a Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 : CIA-RDP81-01043R002300040009-9 atom can can be strongly hydrogen bonded, namely the carbonyl V. *0 oxygen. The formation of two or more strong hydrogen bonds would therefore be sterically hindered or prohibited in ethanol and aniline solvents. This possibility has been considered previously for another solute by Professor G. Pimentel in a discussion of solvent spectral shifts ?28 (28) G. Pimentel, University of California, private communica- tion to M. Kasha. Intensities: A simple theory of solvent effects on mero- cyanine band intensities has been proposed by McConne11.29 (29) H. McConnell, quoted by Platt.11 The theory is based on the assumption that the ground and ex- cited electronic state functions for the strong visible transi- tion may be considered as linear combinations of the electronic state functions appropriate to the isoenergetic point. This assumption differs only formally from that upon which Brooker based his interpretation of the frequency shifts. There results Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: Declassified in Part- Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -26- = (5) where f and respectively denote the oscillator strength and frequency of a band, and the subscript refers to the iso- energetic point. The theory is not supported by the results of the present work. Whereas the frequencies of the bands of known inten- sity undergo a total variation of 20% and 30% for dyes I and II respectively, the oscillator strengths show no progressive variation with band frequency beyond the experimental error of 5%. With dye III, the band frequencies do not cover a sufficiently large range to permit a valid test of the theory. Band Shapes: Platt11 has shown that Brooker's interpre- tation of the frequency shifts can be extended to explain the concomitant changes of band width. At the isoenergetic point, the equilibrium nuclear configuration of the dye does not change upon excitation, so that only the 0-0 vibronic band appears strongly. As the solvent representative point moves away from the isoenergetic point, the equilibrium length of each bond in the C-C chain suffers a progressively more pro- nounced change upon excitation. According to the Franck- Condon principle, this should lead to the growing up of higher-frequency vibronic bands at the expense of the 0-0 band with frequency separations corresponding to the C.-C stretch- ing frequency. The above interpretation is strongly supported by the results of the present work. The absorption curves corre- sponding to representative points near the reversal point and Declassified in Part - Sanitized Copy Approved for Release 0 50-Yr 2013/09/13 : CIA-RDPRi_ni nit-4 Pf1(1t-Inn nnt-srs Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 on the weakly polar branch ture, which changes in the sentative point moves away separation of the vibronic factory agreememt with the Vibrational structure does corresponding to points on because of the blurring of -27- show definite vibrational struc- predicted manner as the repre- from the reversal point. The peaks (1000-1100 ce-1) is in satis- C-C stretching frequency. not appear in the absorption curves the highly-polar branch, probably structure normally associated with strong solvent-solute interaction. Nevertheless, the broaden- ing may be attributed to changes of the relative intensity of the underlying vibronic transitions. It can be seen from the absorption curves that if it were possible to plot E max against the 0-0 frequency rather than against Ilmax, the highly- polar and weakly-polar branches would be nearly superposed. This tends further to substantiate Platt's interpretation, since the ground and excited-state potential energy curves for C-C stretching are presumably nearly symmetrical near their respective minima. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? -28- Acknowledgements: Most of the work described above was carried out under the supervision of Professor N. S. Bayliss, to whom the writer is indebted for encouragement and helpful criticism. The writer is glad to thank Dr. L. G. S. Brooker for the gift of the merocyanine dye samples, and Professors N. S. Bayliss and M. Kasha for reading this paper prior to publication. Financial assistance provided by the University Research Fund (University of Western Australia), including the award of a studentship, is gratefully acknowledged, as is also the award of a Hackett Studentship by the University of Western Australia. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 TABLE- 1 SOLVENT DESIGNATIONS AND PROPERTIES Solvent Desig- nation Da Benzene 2.3 Dioxane Chloroform 2.2 CF 5.2 Nitrobenzene NB 35 Pyridine Ace t one 12.4 Ac 21 Aniline An 7.3 - Ethanol 28 Formamide 109 Water W 79 F(D,A3)e 2 1 n D 2n2D r 1 1.4-98 0 0.23 1.421 0.03 0.20 1.446 0.32 0.21 1.555 0.60 0.24- 1.511 0.49 0.23 1.359 0.65 0.18 1.586 0.34 0.25 1.363 0.68 0.18 1.448 0.71 0.21 1.333 0.76 0.17 (a) Dielectric constant (b) Refractive index (sodium D (c.) F(P_1nD) = (D - 1)/(D t 2) - (n2'- ) /(Z2 t- 2) Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Co.y Ap roved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 TABLE 2 DYES 1-III IN PURE SOLVENTS Solvent Vmax x 10-4 (cm-1) Dioxane 1.864 1.559 III 1.838, 1.947a 1.773 Chloroform 1.883 1.570 1.888b Nitrobenzene 1.920 1.629 1.753 1.85313 1.768, Pyridine 1.935 1.638 1.883u 1.804 Acetone 1.970 1.681 1.920 *Aniline 1.986 1.690 Ethanol' 2.071 1.002 2.333" Foimamide 2.115 1.890 2.351d 2.292 2.132 2.028e Water 2.615? 2.4800 2.463f -3 max 10 I 11 III I 11 III 58.0a 82.5a 53.0a , 52.6a9u 74.0 103.5 90.4 50.41) 89.0, 66.5 92.9 49.7" 98.0 80.5 112.8 58.ob 76.0 78.0 103.6 50.5b 67.5 79.3 0.65 0.74 0.82 0.63 0.79 0.80 - 0.70 0.91 0.81 0.74 0.94 0.74 0.64 0.82 113.0 51.0 510.7 41.4d 0.90, 0.62 0.85 0.82a 46.0 42.5 35.9d 0.62 0.82 0.73d 37.5 36.7 43.3! 29.00 26.0c 33.5' 0.63 0.80 0.74e 0.62c 0.80c 0.72f (a) Adjusted to conform to an oscillator strength equal to that for the same dye in water. (b) Refers to a second maximum. (c) Protonated dye. Solvent: 0.26N HCL. (d) Protonated dye. (p) Solvent: buffer solution, RH 9. .(1) Protonated dye. Solvent: buffer solution, pH 6. Declassified in Part - Sanitized Co .y Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040nmq Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 TABLE 3 DYE II IN MIXED SOLVENTS Solvent Mole%a 'max x lo -4 (cm-1) x 10-3 ma.x Dioxane-water Benzene-pyridine Benzene-acetone Acetone-water 95.0 1.570 90.0 90.0 1.590 85.5 78.4 1.660 62.0 64.2 1.713 59.0 44-.6 1.770 49.8 20.0 1.885 43.0 11.7 1.958 40.4 98.1 1.533 76.2 1.636c 56.40 78.2 1.554 90.7 - 52.7 1.589 102.0 - 24.6 1.618 90.0 98.3 1.534 75.2 1.631c 53.7c 94.9 1.542 81.4 - 91.7 1.549 100.0 - 78.9 1.573 105.2 0.84 49.3 1.618 117.7 0.93 37.0 1.632 109.0 0.89 12.4 1.661 105.0 0.94 99.0 1.682 106.5 0.96 95.4 1.695 103.8 0.99 72.4 1.750 66.4 0.89 57.9 1.776 63.8 0.91 35.6 1.870 47.0 0.82 22.2 1.927 46.0 o.86 9.4 2.010 38.4 0.77 =IP OM. WEI 41=11 Om ftellet (a) Refers to first-named solvent component. (b) Where no oscillator strengths are given, the extinction coefficients are adjusted to conform to.an oscillator strength equal to that for the same dye in water. (c) Refers to a second maximum.. Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part- Sanitized Copy Approved for Release 50-Yr 2013/09/13 : CIA-RDP81-01043R002300040009-9 TABLE 4 DYE III IN MIXED SOLVENTS -2b Solvent Mole 11max x 10-4(cm 1)max x 10 1.813 Dioxane-water 96.3 1.9250 1.791, 88.7 1.908? 77.7 1.785 61.1 1.791 42.2 1.803 23.1 1.835 12.0 1.892 Benzene-pridine 98.9 1.835 1.930e 70.3 1.798 1.914e 46.3 1.784 1.895? 22.4 1.775 , 1.890e , 1.766 Pyridine-water 92.3 1.876e 82.0 1.764 48.4 1.785 34.5 1.801 4.2 1.913 0.8 1.992 58.0 50.0c 75.5?, 49.o- 103.5 107.0 96.0 70.0 55.5 52.0 52.470.5c 60.51/4* 84.0 60.5c 93.0 6o.oc 112.0, 56.5`' 125.5 1?4.5 77.0 55.4 45.5 .11 SIM 11. 0.83 0.86 0.86 0.84 0.85 0.80 0.72 0.82 0.78 (a) Refers to first-named solvent component. (b) Where no oscillator strengths are given, the extinction coefficients are adjusted to an oscillator strength equal to that for the same dye in water. (c) Refers to a second maximum. Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13 : CIA-RDP81-n1 OLVIRnn9qnnnAnnrm De I in a - C A for Release - r 2013/09/13: CIA-RDP81-01043R002300040009-9 - (Captions for Figures) Fig. 1. E max vaL V max plot (schematic). Fig. 2. Absorption curves for dye I in pure solvents. For solvent designations, see Table I. A prime indi- cates an absorption curve for the protonated dye. Fig. 3. Absorption curves for dye II in pure solvents. Fig. 4. Absorption curves for dye II in acetone-water and benzene-acetone mixed solvents. The numbers denote mole percentages of the first-named solvent component. The curve for pyridine-water solvents is redrawn from the data of Brooker et al.4 Fig. 5. C vs.max plot for dye II. max Fig. 6. Absorption curves for dye III in pure solvents. Fig. 7. Absorption curves for dye III in benzene-pyridine and pyridine-water mixed solvents. Fig. 8. Emaxma. max plot for dye III. Fig. 9. (No caption). Fig. 10. (No caption). Declassified in Part- Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81 nin4Wnn9q(1(1(lArtririn Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 TOX 100 niREVERSAL POINT HIGHLY POLAR BRANCH WEAKLY POLAR BRANCH 5000 ? V max X (A) 4000 80 6 x10-3 60 CF NB Ac 40 20 ? 1.8 2.0 2.2 12.4 4 2.6 V (cm) 110- 3.0 Fi4 1 Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 7000 6000 MA) 5000 80 ? x10- 6 0 7000 6000 MA) 4000 5000 B-Ac r% f ;00 j I I % 0(Ac) 1 7100 (Ac) 1 12.4 I 80 1 I 78.9 Ik 1 ? xo 98.3 I\ ,-724 60 II V \ \ I I 1435'6 It , -, 0(W) I 1\ v \ N\ 40 I I \ \ ? I i 4 \ \ \ ? I i ,\ ? I f / / \ / hI// 1.4 1.6 1.8 2.0 2-2 v (cm-1 ) XIC)-4 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 120 100 emax X10-3 80 80 40 20 100 80 ? x10-3 60 40 20 0 6000 ? 1 NB An ? 5000 B-Ac Ac-W D-W 2.0 x(4) HC (CH?CH ?C' ............. 1 22 24 VMOX (CMI)x104 4000 1 1 1 I I 1 I NB Ac WI 00"c=cH-Cliam(D-0 CH3 VN 1.6 1.8 2.0 2.2 2.4 V (cm-i)x10-4 2.6 2.8 2.6 Fig. 6 Vb. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? ? 12 roo 80 6 x10- 60 6000 5000 V IT JJ B-P 40 20 0 1.6 1.8 2.0 2.2 V (CM-1 X i0-4 98.9 1 1 1 1 4000 CO'CNECH-CH->- 0 P-W CH3 82.0 100(P) 0(W) \\ \N ????.. 2.4 - Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 tt 1.3 25 - V MO X(CM-1)X104 s. Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 F. EmaxxICr3 SO $O 40 P-W D-W B-P >=CH?C14:=0=0 ells ors .......... .................... . ?Wi ti ; Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release r;g. 9 ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 .,? 0-6 0-5 0-4 F 0?3 0-2 - 0-1 - ? ? ^ NB . ?P CF. ? PURE SOLVENTS ABP i ? A0 A70.3 1.75 1-80 v max(cm-1) x10-4 ?D 98.9A 1 1-85 Fig. 10 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? %MAW. --vfe-vo.,r44t4tam.Qsth.i4OeV, INTRAMOLECULAR TWISTING EFFECTS IN SUBSTITUTED BENZENES. I. ELECTRONIC SPECTRA.1 '2 By Eion G. McRae and Lionel Goodman Departments of Chemistry, Florida State University, Tallahassee, Florida and The Pennsylvania State University, University Park, Pennsylvania. 1 Taken from a dissertation submitted by E. G. McRae for the degree of Ph.D. at Florida State University, 1957. Presented in part at the symposium on Molecular Structure and Spectroscopy, Columbus, Ohio, June 1955. 2 The work was carried out under a contract between the U. S. Air Force, Office of Scientific Research, ARDC, and the Florida State University. Supported in part by a grant from Research Corporation. 3 Present addresses: E. G. M. -'Chemical Physics Section, C.S.I.R.O., Melbourne, Australia; L. G. (to whom reprint requests should be addressed) - Department of Chemistry, Pennsylvania State University, University Park, Pennsylvania. (Abstract) The electronic spectral effects of twisting a substituent group about the substituent -ring bond in substituted benzenes are analyzed from the viewpoint of semi-empirical MO theory in- cluding zeroth and first order configuration interaction. The substituent orbital iso is expressed as a linear combination of two functions, Ox and Or which are respectively anti-symmetric and symmetric with respect to reflection in the ring plane: 1. cos eOx 4- sin 9 fy.. Transition energies and intensities are discussed with reference to the twisting parameter 9. ? Ordinarily, 9 increases as the substituent is twisted, and can Declassified in Part - Sanitized Copy Approved for Release @P-Yr 2013/09/13 CIA RDP81 ni nLVIR nn'Y4nnflA nrInn Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 be evaluated explicitly when the molecular geometry is known. The treatment is carried through both with and without cogni- zance of the nearest-neighbor overlap integrals, and the in- ductive effect of the substituent is discussed. Particular attention is given to the question of self-consistency. The theory applies especially to those transitions which correspond to transitions observed in the spectrum of benzene ("benzene-analogue" transitions). Three possible types of ()- dependence of transition energies are distinguished, and the conditions under which each might be realized are specified. Of the four benzene-analogue singlet-singlet transitions con- sidered, the two of lowest energy are ordinarily predicted to suffer a decrease of intensity as A increases, while the inten- sities of the remaining two transitions are predicted to be insensitive to twisting perturbations. "Charge transfer" transitions are also considered, though in less detail. The theory is applied in a detailed discussion of the ultra- violet absorption spectra of N,N-dimethylaniline and related molecules in which the dimethylamino substituent is twisted as a result of ortho substitution or intramolecular bridge formation. Declassified in Part - Sanitized Copy Approved for Release @P-Yr 2013/09/13 CIA RDP81 ni nLVIR nn'Y4nnflA nrInn Declassified in Part- Sanitized Cop Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? 1. INTRODUCTION vorl&-sigo--...VOrlatiArimitist."1,,arkrastxttgsst4:2.. In several series of substituted benzenes, the twisting of the substituent group about the substituent-ring bond leads to pronounced changes in electronic properties. For example, the effect of twisting is revealed particularly clearly in the spectra and some ground-state properties of N,N-dimethylaniline and related molecules.4-8 In this and other series of substituted if 5 B. M. Wepster? Rec. Tray. Chim. gtz, 411 (1948); 1159 (1952); , 335 (1957); 2k, 357 (1957). B. M. Wepster, Rec. Tray. Chim. 23w, 661 (1953). 6 H. B. Klevens and J. R. Platt, J. Am. Chem. Soc., 17.19 1714 (1949). 7 W. R. Remington, J. Am. Chem. Soc., 6Z, 1838 (151+5). 8 9 Ref. 4-7 are to literature on spectra. including references to the literature ties, are given in the following paper Further references, on ground-slate proper- (paper II).Y E. G. McRae and L. Goodman, J. Chem. Phys. za, 0000 (1958). benzenes, twisting may be produced either as a steric effect of ortho-substitution, or as a result of intramolecular bridge formation. This paper is devoted to an analysis, from the molecular orbital (MO) viewpoint, of the effects of twisting perturbations on substituted benzene spectra. In the following paper9, we apply a similar theory to ground-state properties such as dipole moment and resonance energy. Declassified in Part - Sanitized Cop Approved for Release 50-Yr 2013/09/13 CIA-RDP81 01n4Rnn9qnnnAnnno Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -2- 2. GENERAL APPROACH We consider a substituted benzene in which a particular substituent group is attached to the ring by a bond between the substituent atom, 7, and the adjacent ring carbon atom, 1. The other ring carbon atoms are numbered consecutively around the ring (See Fig. lb). The 1-7 bond is assumed to lie on the pro- jection of the line joining carbon atoms 1 and 4, but the sub- stituent group itself is supposed not to be axially symmetric with respect to the 1.4 line. Let us suppose that the substituent interacts conjugatively with the ring via the single atomic orbital (A0) is?, centered on 7. We assume that in the ground configuration there are formally two electrons in ?scs. In a future publication we shall consider the case of a substituent with several AO's capable of interacting with the ring carbon 201r AO's.10 10 L. Frolen and L. Goodman, work in progress. We wish to discuss the spectral effects of twisting the substituent group about the 1-7 bond. The effect of twisting is observed experimentally as a regular relationship between the spectra and the twist angle1112. In order to discuss twisting 11 The observed spectra should be corrected, if necessary, to allow for the direct influence of the substituent or sub- stituents responsible for twisting. For an example, see Table 6, footnote (b). 12 The definition of the twist angle is arbitrary to some extent, as there are in general various ways of incorporating the part of the twist angle corresponding to the change of shape of the substituent as it is twisted. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDP81 ninaq 11119qrIlln A nnnn n Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -3- effects from the theoretical viewpoint, we express is? as a linear combination of two normalized functions, Ox and 07, which are respectively anti-symmetric and symmetric with respect to reflection in the ring plane: is? = cos 0 ix 6, sing fy ? (1) We require that Ox remain effectively unchanged during the twist- ing of the substituent. However, we place no such restriction on O. Because of its symmetry, the function Oy in Eq. I may be assumed not to interact appreciably with the ring 17-MO's. Consequently, the parameter 9 enters into the theory in a par- ticularly simple way. For this reason, and also because the twisting of the substituent ordinarily corresponds to an increase of 9, it is convenient to break the problem into two parts: First, to deduce the 9-dependence of the spectra, and, second, to relate 9 to the angle of twist. In this paper, except where otherwise mentioned, we will be concerned with the first part of this program. The second part is difficult to treat generally; it could easily be carried through for any particular substituted .benzene if its geometry were known. If fs? is a pure 2p AO, the parameter 9 takes on an especially simple meaning; it is the angle of twist of ks?, and hence of the substituent group, with respect to the ring plane (Fig. lc). For the substituted benzene, we anticipate four low-energy singlet excited states, corresponding respectively to the Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01041Rnn7qnnnAnnna 0 Declassified in Part - Sanitized Co .y Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 7 following states states in benzene: 1B2u (energy )+.9 e. v. above ground state, 1Bin (6.2 e. v.) all.: the components of lEiu (7.0 e. v. ). In the foregoing, the benzene state energies refer to the absorption band centers, the symmetry designations pertain to the Doi group, and the assumed assignments are those ? fairly generally accepted at the present time.13 We shall 13 D. P. Craig, Revs. Pure and Applied Chem. (Roy. Australian Chem. Inst.) a, 207 (1953). refer to the above states of the substituted benzene as "benzene analogue" (BA) states. In addition to the BA states, we antici- pate at least two low energy singlet "charge transfer" (CT) states, arising formally from the excitation of one of the sub- stituent electrons to a vacant benzene 11-140. For each of the above states, we naturally anticipate a corresponding low-energy triplet state. In particular, we expect a lowest-energy trip- let corresponding to B in benzene (absorption band center 13 3.8 e. v.). The treatment of CT transitions is rendered comparatively difficult by a number of factors, among which may he mentioned the possible inapplicability of the approximation in which the same effective Hamiltonian is deemed appropriate to both the ground and the excited states. A detailed discussion of that question is beyond the scope of the present work. Accordingly, only the BA states are treated in detail in this paper. The CT states, and the possible importance of BA-CT configuration inter- action are also discussed, but in a purely qualitative way. Declassified in Part - Sanitized CO.y Approved for Release 50-Yr 2013/09/13 C 1 - I f") nrtrt et " " Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 3. TREATMENT OF BENZENE ANALOGUE TRANSITIONS The method of treatment adopted in this paper is based on the semi-empirical MO procedure developed by Goodman and Shull, 14. L. Goodman and H. Shull, J. Chem. Phys. 220 33 (1955). and applied by them in a systematic interpretation of the spectra of substituted benzenes.15. The above two papers should be con- 15 L. Goodman and H. Shull, J. Chem. Phys. 22, 1388 (1957). suited for those details of the method which are omitted in the present paper; to facilitate reference, the notation in the present paper has been made to conform as closely as practicable to that of Goodman and Shull. Zeroth Order: - In the zeroth order of approximation, in which the substituent is considered not to interact with the ring, (Fig. la) the orbitals fpr the substituted benzene comprise the substituent AO fs?,,and the benzene 1T'-MO's. We denote the 10.4-4-evo .1.171WW?OA. ii? (i 8.01 1, 1, 2, 3), and express them as linear combinations of AO's (ICAO): 6 - o c544 Ofi. 9 = 1 where 0/14, denotes the 2p/r AO belonging to atom, a , all AO's having positive lobes on the same side of the ring plane. The value of the carbon AO Coulomb integral, ,.is chosen as the zero.of MO energy, and the orbital energies are expressed throughout in terms of the semia,empirical.CC resonance integra11/5 (2) Declassified in Part- Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81 nin4Wnn9q(1(1(lArtririn Declassified in Part- Sanitized Cop Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -6- In the zeroth order, let ei? denote the energy of the orbital ii?. We write ei = ni where ni? is the orbital energy factor for The AC co- efficients and energy factors for the benzene MO's, either with or without nearest-neighbor overlap integrals included, may be obtained from the formulas given by Wheland.16 For the C-C 16 G. W. Wheland, "Resonance in Organic Chemistry", John Wiley and Sons, New York, 1955, p. 666. overlap integral in benzene, the value 1/4 is adopted for cal- culations with overlap included. The barred and unbarred MO subscripts respectively signify MO's belonging to A and B reps (irreducible representations)17 of the C2 group (see below). 17 M. A. Melvin, Revs. Mod. Phys. aai 18 (1956). Intramolecular twisting destroys the C2v symmetry of a sub- stituted benzene, and in this paper we assume that the effective Hamiltonian has C2 symmetry. Accordingly, we adopt the C2 symmetry classification of wave functions, and consider only those interactions which are between functions of the same C2 symmetry type. As a particular consequence of the destruction of the C2v symmetry by intramolecular twisting, it is no longer strictly meaningful to draw a distinction between W-- andlc Ir-electrons, because a Molecule with a twisted substituent group no longer has a plane of symmetry containing the con- jugated atoms. However, the ring carbon AO's which are anti- Declassified in Part - Sanitized Cop Approved for Release 50-Yr 2013/09/13 ? CIA RIWRi_ninit Prirv-y)r-Inr, A nnn, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ....mnerastemungINOICIIIIMIIIMMOINIPINOMPhk -7- symmetric with respect to reflection in the ring plane may be distinguished from the other ring carbon AO's, and it is con- venient to refer to them still as 2pIr AO's and to the occu- pying electrons as 71'-electrons. Similarly the two electrons in the substituent AO fs remain sharply differentiated from the other substituent electrons. For similar reasons, the Te-electron approximation is no longer strictly applicable. We retain it in, the sense that we consider interactions between only those AO's which are anti-symmetric with respect to re- flection in the ring plane ---viz. fx and the ring carbon 207-A0ts. The ground state function is approximated throughout by a single (closed shell) configuration function, and the zeroth- order ground state function is denoted by 00. The zeroth- order state functions for the substituted benzene must be built up from the orbitals with due cognizance of zeroth-order con- figuration interaction (CI). There results, for the four low- energy singlet excited states, 4 O , - 2-1/2 (x12 - x/2,, I24'1/2 (xl 2 12 -1/2 o o - 2 , (x12 12 x- ) o y . - r1/2 (X% ?x?? ) le 12 9 (3) where x12, for example, denotes the zeroth-order singlet con- figuration function arising from the configuration . )2 0) 2 4 1 1)2 2)1. Similar expressions can of course be Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDP8i-ni naqpnno nrInArw-,, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -8 - written down for the triplet state functions. In the notation for the state functions, as in that for the MO's, a barred sub- script signifies an A-type function and an unbarred subscript a B -type function. The correspondence between the benzene states and the above functions is as follows: Alg; l''-B; Biu; 212'E1. Interactions: - When the interactions between substituent and ring are taken into account, the new MO's are given in DCMO form, 3 Aij f3 j se sO by solution of the MO secular equation det {111.3 - e Si33 = o. Hij = Her f; d v, (ilj s, 0,1, 1, 1, 2, 3) Here, Heft denoting the ,effective Hamiltonian, and sii ej v. In solving the secular equation, we follow Goodman and Shull, who have described a method for solving Eq. under the following conditions: s15cil r s, Hij in cii e31 difi 9 n?116 r end' 1j5 His sit cii ffi (i s) (i 3, i # st 3 # 5) (i # s) (i # s) (10 ( 5 ) Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01041Rnn7qnnnAnnna 0 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ?9? Here, S denotes the C-C overlap integral, and si7/s where s17 denotes the 1-7 overlap integral. The assumption (6) /917/14 ( (7) is implicit in the expression for His in (5). ignmans the Coulomb integral at atom 7, and dT1/6 represents the increment of the Coulomb integral at atom 1, due to the substituent. Thus, represents the inductive effect Of the substituent. The conditions (5) embody the approximation, frequently Introduced, of neglecting interactions between non-nearest neighbor atoms. Two other common approximations, namely the neglect of overlap and the neglect of the inductive effect, may be brought in through (5). The neglect of overlap corresponds to putting s sl7 = O. This implies that the benzene MO's and MO energy factors are to be taken without overlap. The neglect of the 'inductive effect corresponds to putting 6 = 0. The present problem is characterized by the condition that /7 varies approximately as cos 0, while cr remains approximately constant as the substituent is twisted'. Therefore, we may appropriately specialize the conditions (5) by superposing the following conditions: = /00 cos At (8a) . cr independent of 0, (8h) .14 Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDPRi-ninaqpnno ruin A Declassified in Pad- Sanitized Cop Ap roved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -10 - where po is independent of 9. From Eqs. 7 and 88.118 we have 18 The parameter is assigned different values for the A-type as distinct frd the B-type states. Therefore, in principle, p in 8c should be assigned different values so as to give /17 the same value in all states for any particular value of U. However, in this paper, we adopt for simplicity a single parameter to. = f2ofl cos O. .(8c) The configuration functions are altered as a result of the orbital perturbations. Also, the mixing of configurations is no longer symmetrical, the new state functions being determined by solution of the state secular equations.15 The new state functions are of the form pi . co. ( 1T14f - AA) x12 - . sin ( 11/4 - AA) x12 4. sin( 11/4 - AA) xn cos ( 7r/4 - A)x -A' / 1 cos ( - B) x6.2 sin ( 104- - AB) x/2 , i2 sin ( irA - AB) x3.2 - cos ( - A ) x B- 12 / (9) where AA and AB are numbers measuring the asymmetry of mix- ing between the respective pairs of configurations. In order to evaluate "As AB and the BA state energies from (9), it is necessary first to evaluate the configuration energies and CI integrals. The former are given in the semi- empirical method as orbital energy differences, i.e. ej - ei = (nj - ni)fi 9 where the MO energy factors are obtained from (4), and is evaluated empirically. The CI integrals may be evaluated with (10) - Declassified in Part- Sanitized Cop Approved for Release 50-Yr 2013/09/13 ? CIA RIWRi_ninit Prirv-y)r-Inn A nnn, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 VD -11 - the aid of the approximation15 Mij lkA, ail aj j akk att where Mijtia. is a general MO electron repulsion integral and MulkL 0 denotes the corresponding integral for benzene. Then Hti. and Hg can be expressed in terms of the zeroth-order integrals (benzene integrals), H?A and H?B respectively, and the latter may be evaluated empirically. k similar method applied to triplet states.. The empirical parameters are evaluated from the spectrum of benzene, as described in Ref. 15. The values of the parameters used in the present work are shown in Table 1. From Eq. 9 the transition moments governing the BA transition intensities are given by MI -- cos AA 4 4- sin AA tit2 62 - -sin AA - NI e.. c OS A A 4 _ - c os A B 4 ? sin AB 4 tf2 = --sin AB 81 r cos A mt B ?2 (12) Here Mil for example, denotes the integral Sio d v where is the perturbed ground state (one-configuration) function and M denotes the classical dipole moment vector. .4 and 0::2 correspond to the allowed components of the Aig Elu transition in benzene, but are modified by the orbital perturbations. Declassified in Part- Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDP81-ninaqpnno (-Inn Ant-. Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -12- Thus, for example 2-1/2 jr 0 M (x12 x--) d v. 12 Mi and Mi similarly correspond respectively to the forbidden Alg Blu and Aig B2u transitions in benzene. The orbitally perturbed transition moments, 4, etc., can be evaluated in terms of the C-C distance in benzene. The method used in this paper is to express the transition moments In terms of the appropriate integrals involving MO's, to expand those integrals in terms of AO integrals, and to evaluate the AO integrals by the formulas 0.4 ? tel o, dv Ervtt. dv (1/2) ? rp ) s?,,y , ( /1.4, .1) ) where rilk denotes the position vector of the,m,th atom, 8 ? j'?Ofy dv, and C stands for the electronic charge. For (13) simplicity, the 1-7 bond length is assumed equal to the C-C distance. For the purpose of calculating BA transition ,intensi- ties, we choose the C-C distance to be 1.0 i; with that value, , Eq. 13 reproduces the observed oscillator strength, f 1.2, for the Algu transition in benzene vapor.19 19 L. W. Pickett, M. MUntz, and E. 21, 4862 (1951). J. Romand and B. Vodiar, Compt. M. McPherson, J. Am. Chem. Soc. rend. lal, 930 (1951). 4. FOUNDATION OF THE METHOD We describe the foundation of the semi-empirical method with reference to a formal LCAO SCF treatment of Intramolecular Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDP8i-ni naqpnno nrInArw-,, Declassified in Part - Sanitized Copy Ap roved for Release ? 50-Yr 2013/09/13 : CIA-RDP81-01043R002300040009-9 4.211 -13 - twisting perturbations in substituted benzenes. We pay special attention to the conditions (8), which for the purpose of the present problem are superposed on Goodman and Shull's con- ditions (5). Also, we discuss the constancy of the important empirical parameter g . Where feasible, the discussion is supported by numerical calculations. SCF Method:--Following a procedure similar to that described by Roothaan,20 we consider the derivation of the "best possible" 20 C. C. J. Roothaan, Revs. Mod. Phys. ga, 69 (1951). LCAO MO for the ground configuration of a substituted benzene represented by Fig. lc. We begin with the same orbitals as before, namely the benzene MO and the substituent AO 07(07 !n). For 0 . we adopt the form (1). The ground configuration MO 7' energies and MO are found by the iterative solution of the secular equation where Fij r 0 detij - g S = 0, F volving the Hartree-Fock Hamiltonian, F. In the first cycle of the iterative process, the Hartree- Fock Hamiltonian is constructed with the zeroth-order MO's (Eq. 2). In a given subsequent cycle, the Hartree-Fock Hamiltonian is constructed with the MO's resulting from the previous cycle. Let ct (It = s, 0, y, 22 3) denote these dv is an MO interaction integral in- MO's and let ir denote summation over the subscripts of the Declassified in Part- Sanitized Co.y Approved for Release 50-Yr 2013/09/13: Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -14- MOlk occupied in the ground configuration. Then the MO inter- action integrals of the cycle in question are given in con- ventional notation by - j(T Fii 1 90- ? dv t?7 (II q? ?) 2(ficik;WP-(fki7;Okri) where T denotes the electronic kinetic energy operatio4U c/.4, the electrostatic potential due to the/a, th core, and in the notations for the electron repulsion integrals, the functions of one electron are written on the left and those of the other electron on the right. The above MO interaction integrals may be expanded in terms of the changes in the AO interaction integrals = F i5, dv resulting from the interaction between ring and substituent. Let F? denote the Hartree-FoCk Hamiltonian for the situation represented by Fig. la. The change In L is given by Then we have and A L 6 6 F -dv - 1.64, F? six 'dv. F44 LI JE. C C .1.4 #44 la ji =1 V4' ix) 6 0 Fii = ? .ca ,A? =1 or. 94' F = ;E: 6 c 4L,7, Fss = e ? AL77. , 3; i, j 5) z L/444, , s) (i i 5) (110 Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-fl1n4flRnn9-4nnnAnt-mn Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -15- Comparison of Semi-empirical ard SCF Methods:--We shall assume for the moment that all bond lengths are independent of 0, in which case condition 8(a) is automatically satisfied. On comparing corresponding semi-empirical and SCF NO integrals in Eqs. 5 and 14, we see that in order to substantiate con- ditions 8(h) and 8(c) we must have respectively: L77 independent of 0, L - L7 cos et (AA_ 17). .44-7 '44 Also, in order that /9 be independent of 0, we must have: 4 1 independent of 0, (A, As explained later in this section, the above condition is necessary but not sufficient for the constancy arig We first consider the 0-dependences of the SCF AO integrals in the first cycle of the iterative process. We have =(107:0!01.1)) 4.2(137070,,44-13.1))41371f.i4 ;15761 )9(AIP 47) = sr 7 5/47 z6 : 07) 0 r [ 2(t!,4057) -(1 t;c ; 1: 07) , i 7) kk'6' "17167) Isk 4i1); '137?7)4 157 ?k?t57)3 ? (07 07; 47 i7). We may express each core integral as the sum of a penetration integral and an AO electron repulsion integral,21 ? e.g. (15) 21 M. Goeppert-Mayer and A. I. Sklar, J. Chem. Phys. 6, 645 (1938). Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 $i 02) (12.14' : 151 02) - (#41,!f,44- : 152)P where triA, denotes the electrostatic potential due to neutral On expressing 07, where appropriate, in the form (1)1 we obtain da LA40 (ii : 'Sy ) c (15xf&O,44 ) (044- ;f5x?51/ ) os2 g. 2 (tiziy.;6,44, ) - (044, ;034 ) cos 9 sin 0 r (034;144, ) ( SOCA, ;clip ) sin2 0 Ca., V A a) r o 6 .44-7 s sAzx (U.a- I 1/04. tCx) t. AL al occ C [2( lc(); ffx) ke. /14" ;i: ox)] 0,44, ; ix)] occ , 6 L77 (11 : 07 07) [2( kO;Ox 0x) ix; -/44,k ? (?4,15//.4. ;t5x 03c)i cos2 0 ie 2 r 2(i ko ko;0x -y)k L -(-o k ex; f: iy)J ?; ss 11,4& x '15r) 1 cos sin [2( kc) k?; Oy tly) k 7.1c (io ; Ao 0w)] 6 ?Z (Ii?, ; 0y) .? 81n29 frxi - (07 071- 07 07). In the expression for LA7 the notation sAta = dv has been, introduced, and we have taken note of the vanishing of all cos e (.As) Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part- Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -17 - integrals in which 'Sy appears only once. It is seen that in the approximation we are considering (first SCF cycle, bond lengths fixed), the integrals L/.47 are strictly proportional to cos 0. A detailed discussion of the 0-dependence of the integrals L/44, (,14.,y 4 7) and L77 would require the knowledge of all the relevant penetration and AO electron repulsion integrals; however, some general conclusions can be drawn by referring to tables of two-center AO Coulomb integrals22,23 ( we neglect three- and four-center integrals, 22 23 R. G. Parrand and B. L. Crawford, J. Chem. Phys. 114 1049 (1948). C. C. J. Roothaan, "Tables of Two-center Coulomb Integrals between is, 2s, and 2p Orbitals", Special Technical Report, University of Chicago, 195$. which are relatively small). If we take 4 to be a 2p AO with axis perpendicular to the ring plane, and assume in turn that idy is a 2s AO and either of the two 2p AO's orthogonal to 4, in no case do we find (4 /1,40!,st.) and (0y 160 J1144,44) to differ by more than about ten per cent. Also, these integrals are at least an order of magnitude greater than the largest integrals involving both idx and 'dye It follows that, in the first cycle of the iterative process, 1,,,ax (AGP 7) and L77 are nearly independent of 0. We now discuss the more realistic case in which the Hartree-Fock Hamiltonian is constructed with MO's of the general form ik = f.aki = s, 0, * 1). Retaining only the one-center and two-center Coulomb electron repulsion integrals, Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R00230004nnnq_o Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 we find L = (U07' ere IS- ) /4)) ?18- - 1/2 4 r!so, (Ida. ;95.1) t5y )1(/44 V;Ap .3) 4 7) 4 LI., = (u7 :0 ) .1/2 419A (ei4- '0 . " /5 0 ) c /44 ,1?4 6 I. v ) + "417(44. ;15707)/ 6 LA47 =e sAku e. (13$44. rd1,44 157)- 1/2 31,4* 7(14, 4. 07,57) l( /AcX 7) /4,-- 6 and 4 L? = (lje :07$7) * 1/2 4 Q7 (e7o7, '57,57) (151) la A 6 + .9),? ,,c=1 where occ 2 2 eE k 4-1 n 0 , A p '4/44. 1Sa' gj "44' aki Ci/A. 9 akj CD) j:444. v (superscripts denote zeroth-order quantities). If the MO's are derived with neglect of overlap, Q/41 repre- sents the Tr-charge density at the /44th atom, and pay represents the order of the Tr-bond joining atoms,, and 1/. Since the semi-empirical MO integrals Hij have been shown to be of approx- imately the correct form as judged by comparison with the first- cycle SCF integrals F1it is not inappropriate to invoke semi- empirical charge densities and bond orders in order to discuss more fully the foundation of the semi-empirical method. Utiliz- ing the semi-empirical MO's of Table 2 (overlap neglected), Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01041Rnn9Innnennna a Declassified in Part- Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -19- tabulated values of the appropriate AO electron repulsion 1ntegrals2224 and again assuming all bond lengths fixed, we 24 The adopted values were those for an effective nuclear charge of 3A2 a.u. and a nearest-neighbor internuclear distance of 1.4 X (these are the parameters appropriate to benzene itself). find that the integrals L/14 (' A,A. 7). vary (-4- 0.01 e.v.) as " cos 0: LA,7 = k cos 0, (16a) while the integrals L44.1) (1491, 7) and L77 contain additive - parts which vary approximately (4-0.05 e.v.) as cos2 0: (A) ac L1,4), 17/2) 154.), cos2 Oi (,a,IP i 7) (16b) L77 (0) a L77 ( 1T/2) + k77 cos2 9. (16c) The constants 1!./44.y are easily evaluated if it is assumed that the integrals 12,4) are exactly constant in the first cycle; in that case, the values of the constants measure. the 9-dependence of the integrals, resulting from the redistribution of charge accompanying twisting of the substituent. For the integrals /" (iu.i 7) we find (e.v.)24: k -0.17, 1c22 = -0.03, " k33 = smo.65, k44 = 4.0.57. A positive sign indicates that the amount of electron repulsion decreases as 9 increases; i.e., the electrons become more tightly bound as 9 increases. For the integrals LAy (,)/ denoting adjacent carbon atoms), we find 24 (e?v?)-- 'k12 = *0.217 k23 = -0.04, k34 '40.03. A positive sign indicates that the magnitude of 1.,/z" increases as in- creases; i.e., the bond between atoms/kandy becomes stronger Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 CIA RDP81 ninzvIPnno-v-Inr, Ann- n Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -20 - as.0 increases. The integral 1,77 has a slightly greater ()- dependence; we find24 k77 = *0.78 e.v. If the substituent atom 7 were more electronegative than carbon, the value of k77 would be greater. For example, for nitrogen we have25 25 The integral (47 47; 47 47) was assigned the value appro- priate to an effective nuelear charge of 3.9 a. u4 The other AO electron repulsion integrals were assigned the - same values as before. k77? 4.1.02 e.v. It is notewtirthy that the sum(,5,404,,0147$7) is almost independent of 9, so that most of the 0 -depencence of L77 comes from (1/2) 6(47 (4747; 4747). We now consider the effect of the 0-dependence of the 7-1 bond length. Changes in the other bond lengths are relatively small, and are therefore not discussed. Assuming a linear relationship between bond length and MO bond order,26 and assum - 26 C. A. Coulson, "Valence", Oxford University Press, London, 1952, p. 253. ing Li7 inversely proportional to the bond length, we obtain d1-d2 L17 = k17 cos 9 k17 P17 cos2 0 +.... dl Here, d1 and d2 respectively denote the lengths of single and double 7-1 bonds, and k17 is the value of L17(0)/c0s 0 for a fixed bond length equal to 41. A similar formula applies for 017. We note that P17 is almost exactly proportional to cos 09 (the order of the 7-1 IT-bond is of course proportional to P17 cOs 9, in view of Eq. 1). Therefore the second term is Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? ? -21 - really proportional to cos3 9. If we take (d1-d2)/d1g"! 0.2/1.51 and P(9 . 0.3, we see that the second term is not more than five per cent of the first. We return now to discuss the conditions (8). We assume for the moment the is really a constant (see below). Con- dition 8c holds with an error in 0-dependence not greater than five per cent, the error arising almost entirely from the lengthening of the 7-1 bond as 0 increases. A similar remark applies to 8a, but in this case the error arises solely from the bond lengthening. The applicability of 8b may be judged from the 0-dependence of the integral L77. Changes in L77 arise mainly from charge redistribution, although the slight ()- dependence of the AO electron repulsion integrals such as (g5,a, t6/44 08) could also play a part. The calculated change in L77 throughout the range of 9,A-1 e.v., implies a change of dr' of about 0.3 VA: -3 eev.). Previous experience15 indicates that this change, while by no means negligible, is not suf- ficient to upset qualitative conclusions drawn by assuming constant. The question that remains to be discussed is that of the constancy of,. We have stated that a necessary condition for the constancy of /g is that the integrals 1,1441 (14+9) 7) be independent of 0, and the foregoing discussion show that this condition is appraximately satisfied. To complete the dis- cussion, we note that in the semi-empirical method the configu- ration energies are taken to be orbital energy differences (Eq. 10), Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-0104ripnn9qnnnAnnna 0 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -22- whereas in the SCF method the configuration energies are given by =e - - (Jil = Ki) Kil (101) where the els are SCF orbital energies and Ji/ and Ku are respectively Coulomb and exchange MO electron repulsion integrals (the upper sign applies to singlet, the lower to triplet con - _figurations). Now the semi-empirical and SCF orbital energies may be assumed to vary proportionately under perturbations, so that the assumption of a constant A is justified to the extent that the electron repulsion integrals vary in proportion to the corresponding semi-empirical configuration energies. The 0-dependences of the electron repulsion integrals have been introduced through Eq. 11. With the aid of the MO's and MO energies of Table 2 (overlap neglected), we find that the ratios(all a22)2/(e2-e1), (a11)2/(eE - el) and (a22)2/(e2 -el) respectively undergo variations of 30%, 20% and 10% throughout the entire range of 0. The errors come in mainly at values of approaching 900. In the range of 9 between 0 and 45?, the variations in these ratios do not exceed 5%. The semi-empirical procedure for the configuration energies is thus leen to be securely founded on the SCF method, especially at lower values of 0. 5. GENERAL CONCLUSIONS Benzene-analogue Transitions:--In order to arrive quickly at the qualitative Conclusions of the theory, we handle the orbital perturbations by means of second-order perturbation Declassified in Part - Sanitized Copy Approved for Release @P-Yr 2013/09/13 CIA RDP81 ni nLVIR nn'Y4nnflA nrInn Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -23- theory. The MO energy factors are given by an expression of the form ni - ni Ai + Bi cos2 A, (17) where for the constant Ai and Bi we adopt expressions conforming to conditions (5) and (8): cil2 Bi = /002 A c 12 (1 - s n1?)2/(n1?? ). - A term involving di2 has been neglected in the above expression for Al. The effect of overlap on the MO energies is illustrated In Fig. 2. For the BA state energies, three possible types of behavior under twisting perturbations may be classified and interpreted In terms of the relative magnitudes of Bi and B,2 (Note that B1 and B5 are always zero under the conditions specified in this paper). Let us consider either of the two pairs of interacting configu- rations, and the states arising from them. Where I B11 >, 1B21, both state energies increase initially upon twist (increase of 0). We designate that behavior as Type i. Where the lower state energy initially increases and the higher state energy initially decreases upon twist, we speak of Type ii behavior; it would appear if (B11 11321 . Finally, where IBil 44 IB21, both the state energies would initially decrease upon twisting, and we refer to that behavior as belonging to Type iii. The three types of behavior are illustrated in Fig. 3. The above classification is based on the, Initial behavior as 9 is increased. The theory does not necessarily imply that the state energies should vary monotonically with 4; Non- Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13 ? CIA-RDP81 nin4npnn9qnnnAnnr,r, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? monotonic behavior behavior could result from the variation of the CI integral. Also any non-monotonic trend in the mean configura- tion energy, such as might arise as a result of deviations from (17), could be reflected in a similar trend in one or both state energies. Twisting effects on the BA singlet-singlet intensities depend primarily on the variation of the /1's in Eq. 12 rather than on the much less marked variation of the orbitally perturbed transition moments. Now for either pair of interacting configu- rations, the appropriate ( lijk or Al B) approaches zero as the configuration functions become more nearly degenerate; Keeping that in mind, the qualitative intensity predictions of the theory may be inferred by inspection of Eq. 12. Let us first consider the case where both the inductive effect and the overlap integrals are neglected. We have A A2 (B11 - - 2 B1( 0 B21 (18a) (18b) In view of (18b), each pair of transition .energies must conform either to Type i or Type ii behavior. Because of (18a), the configuration energies become degenerate at 9 = 1T/2. The theory OW thus predicts that the 6 and 0 ?01 transitions should each shift initially to the blue upon twisting, with a progressive diminution of' intensity. The intensities of the other two transitions should he relatively insensitive to twisting.27 As 27 In speaking of intensity changes, we refer to percentage changes of the oscillator strength. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R007?Innn4nnna a Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -25- 0 approaches 1172, the frequencies and intensities of all four transitions should approach those of the corresponding benzene transitions. Next, we take up the case where the inductive effect is included but the overlap integrals are neglected. In place of (18a), we now have A - A 0 1 - 2 9 and the B configuration energies become degenerate at a value of 0 less than I1/2. The intensity of the 5 ?0.1 transition should initially decrease upon twisting, the transition should become accidentally forbidden at an intermediate value of 9 (cf. Fig 5b), and subsequently the intensity should increase until 0 becomes 1r/2. No other new features are brought in, except in that, when 0 = 17/2, the transition frequencies are no longer expected to revert exactly to the corresponding benzene frequencies. Finally, we consider the case where the inductive effect is again neglected, but the overlap integrals are taken into account. The effect of overlap is to decrease by a substantial amount the numerator of B19 and at the same time to increase that of B2 by about the same amount. Therefore, where overlap is includedi the predicted behavior of the band frequencies tends more nearly to conform to Type iii than to where overlap is neglected. Type i behavior might still be predicted, however, if d' were sufficiently close to n10 As the configurational interaction integrals depend only slightly on the AO overlap integrals, it follows that the calculated electronic state Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R007?Innn4nnna a Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? ? -26- energies are substantially increased by the inclusion of Over- 1ap28 (cf. Figs. 2,4). Since B1 .and B2 may now become equal, 28 In the SCF method upon which the present semi-empirical treatment is based, the difference between the ground and excited state effectivR Hamiltonians is allowed for only in a crude approximation.29 Some preliminary calculations by 29 P. 0. Lowdin, Advances in Physics 1, 1 (1956). the authors3? indicate that, if a more accurate correction 30 E. G. McRae and L. Goodman, unpublished. were applied in the semi-empirical method, the calculated energy of the state would be lowered relative to the ground state (i.e., in opposition to the effect of inclusion of overlap) and the energies of the other three BA states would be increased., A corresponding correction for CT transitions would probably be especially large. there exists the possibility of the 5 I transitions being accidentally forbidden throughout the range of O. In any case, with overlap included, the predicted intensity is smaller than with overlap neglected. Charge - Transfer Transitions:--The lowest energy CT con- figurations, together with the corresponding singlet configu- rational functions, are as follows: s) 1 0)2 1)2 1) 2 2)1; 01 0)2 1)2 1)2 2)1; Xs2 x32. A Although the n -+1t* and fl r -01r* classification of electronic transitions is not strictly applicable in the cases we are dis- cussing here (C2 symmetry), it is helpful and not too inaccurate to think of the CT transition changing from the IT --pir to the Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-0104-iRnn9qnnnAnnn0 0 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -27- n ir* type as 9 runs from 0 to 17/2. Since n -oir* transi- tions are generally weak as compared with those of the 71r471* type, it is to be expected that the CT oscillator strengths should decrease upon twisting. By analogy with n --)fr * tran- sition intensities in substituted benzenes (not heterocyclics), an upper limit for the CT oscillator strength at 0 Tr/2 may be set at 0.001. As for CT transition intensities at 0 < 1172, we may be guided to some extent by the values of the one-configuration transition moments such as iils2 = 1 r3 p-21 d v, which are given in Table 5. It must be kept in mind, however, that the CT intensities could be greatly increased through Interaction between BA and CT configurations.31 As the relevant 3;. Conversely, the BA transition energies and intensities could be affected by low-energy CT configurations. A possible case of this is discussed in Sec. 6. CI integrals all tend to zero (or to very small values) as 0 approaches 1T72, there is no need to revise our conclusion con- cerning the limiting CT intensity as 0 approaches 11/2. 6. APPLICATION TO N.IN-DIMETHYLANILINE AND RELATED MOLECULES. Assignment of Transitions:--The effects of intramolecular twisting on the spectra of N,N-dimethylaniline and related molecules have been studied experimentally by Wepdter,'5 by Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01041Rnn7'Innn4nnna a Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -28- Klevens and Platt6 and by Remington.7 A representative selection of the experimental data is reproduced in Table 6. The structures of the less familiar molecules figuring in Table 6 are shown below. In the molecules listed in Table 5, ortho-substitution or intramolecular bridge formation leads to twisting of the amino group about the bond joining the nitrogen atom to the adjacent ring carbon atom. There is little doubt that the observed intensity changes may be *attributed primarily to intramolecular twisting perturbations, since in the absence of intramolecular twisting, alkyl chloro- or bromo- substitution has a relatively small effect on band intensities. In order approxi- mately to eliminate the direct effects of substitution on the band frequencies, the observed frequencies are corrected by adding the difference between the corresponding band frequencies Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R0071onn4nnno_a Declassified in Part- Sanitized Cop Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -29- for benzene and for an appropriate substituted benzene.32 The 32 The ortho substituent correction of the ? -41 and '6 I transitions in Table 6 represent the difference between the 1 and 0 -.4 1 o-o band energies of benzene and the corresponding alkyl or halo benzene applied to the band maxima of the dimethyl aniline derivative. For the 0 -42,2 transitions band maxima are used throughout. This procedure is justified on the following grounds: The calculations reported in this paper assume the same molecular dimensions in the ground and excited states and therefore apply to vertical transitions. On first thought, this would imply that an experimental band maximum Is to be used for comparison with a theoretical excitation energy. However, the problem is complicated by the 0 1 and 0 I transitions becoming for- bidden, or nearly forbidden as runs to 1172. (The presence of an inductive effect will remove the formal forbiddeness at al 1772, but will in general not change the sense of the following argument.) A weakly perturbed transition may be re- garded as retaining "memory" of the forbiddeness and therefore possesses a weak o-o band.53 In the following series of sub - 33 W. W. Robertson and F. A. Matsen, J. Am. Chem. Soc. 7, 5252 (1950). stituted benzenes of Increasing substituent perturbation (benzene, toluene, chlorobenzene, fluorobenzene), the o-o band In the vapor spectrum increases in strength until the band maximum occurs at the o-o transition. For these cases the ver- tical transition is likely the o-o one. Since our corrections are for the alkyl and halogen groups it seems clear that the substituent correction should be the difference in the o-o band energies of benzene and the substituted benzene for the 0 1 and 0 transitions; but for the allowed 0 transitions the difference in band maxima. These corrections are applied to the band maxima of the Dimethylanilines since o-o forbiddeness is believed to be sufficiently removed for the maximum to be the vertical transition. This procedure may be open to some question in VII, where the 6 -41 transitions show benzene structure and the vertical transition is not completely unam- biguous. We note 'that this implies a small error in our empirical parameters since benzene band maxima were used throughout. corrected band frequencies are given in Table 6. The corrections actually depend in part on the band assignments indicated below. The nine molecules appearing in the table are designed numeri- cally in what is thought to be the order of increasing*twist angle, the twist-angle being defined, following KleVens and Platt,6 Declassified in Part - Sanitized Cop Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81 0104:1Rnn9qnnnA n OF Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -30- as the angle of inclination to the ring plane of the line join- ing the amino carbon atoms. Except for VII and possibly lie, it is not possible to specify, actual values of 9 because the tolecular geometries are not known. On the basis of symmetry, we can say fairly certainly that the twist angle in VII (benzo- quinuclidine) is 900, and that in He (Trogerls base) it probably lies close to 45(:).5 The upper and lower limits for the twist angles are reproduced in Table 7. The figures quoted there provide the basis for the ordering of molecules in Table 6. The parameter 0 cannot be identified with the twist angle, because at a given twist angle 9 depends on the type of hybri- dization of the nitrogen valence orbitals. The values of 9 corresponding to the limiting twist angles are shown in Table 7. From this table, we conclude that 0 increases monotonically with twist angle. The trends in the observed absorption energies and inten- sities are illustrated in Figs. 4a and 5a respectively. The trends in the spectra as the twist angle approaches iir/2 suggest definite assignments for each of the observed absorptions. Thus the lowest-frequency transition, which in I appears weakly (f = 0.04) at 4.2 shifts sharply to the blue with pronounced diminution in intensity. In VII, the band has a- frequency 'very close to that of the Alg B2u band in benzene, and has similar vibrational structure. Accordingly the band may be attributed to the 'BA transition 5 1.34'35 We should not be surprised 34 This is contrary to an assignment made by Klevens and Platt.6 35 See also the similar assignments of Goodman and Shull.15 Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-0104ripnn9qnnnAnnna 0 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? ea, -31 - that the 5 -41 band intensity in VII is considerably larger (by a factor of four) than that of the benzene Ag --o B2u band, since this effect is predicted theoretically (see below). How- ever, the intensities of the other BA bands are expected to revert to those of the corresponding benzene bands as 9 approaches 1T/2. The next band is fairly strong (f 7. 0.28) in I. It loses intensity upon twisting and disappears altogether in VII (f ( 0.001). The band frequency suffers relatively little change upon twisting, remaining close to 5.0 e.v. The transition must be of the CT type; otherwise, its intensity would approach that of one or other of the benzene transitions, all of which have oscillator strengths in excess of 0.001. By similar reason- ing, the band at 6.2 e.v. in I (f s 0.54) may be attributed to the BA transition 5.. As the twist angle increases, the band shifts to the red with a fairly pronounced drop in intensity. Finally, the absorption at 7.0 e.v. in I (f r. 0.79) may be attributed to the remaining two BA transitions, 5 -.4.2 and 5 .? which presumably lie so close together that they appear as one.15 Its behavior is different from that of. the other three bands, in that its intensity' undergoes only a small fractional change as a result. of intramolecular twisting. ThUs, its intensity in VI is twenty per cent less than in I while the intensities of each of the other three bands are diminished by a factor of three or more. Empirical Parameters: - -In order to apply the theory described in Sec. 3, we choose values of (which, for 921,01 lead to Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01041Rnn7'Innn4nnna a Declassified in Part - Sanitized Copy Approved for Release ?50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? -32- approximately the correct intensity for the 1 transitions in I. With overlap neglected, we adopt la 1.5,36 and with 36 In Ref. 15 we have estimated it- 1.0 for I by fitting the energy of the Z5 1 transition. Our conclusions are rather in- sensitive to the particular numerical values assigned to the parameters, except where otherwise noted, and are therefore con- sidered to be fairly generally applicable. We note that the intensity of the ? --k1 transition should be highly sensitive to assymmetry of'chargerlY and thus valid for conjugative parameter 37 L. Goodman, I. G. Ross and H. Shull, J. Chem. Phys. 26, 474 (1957). correlation. overlap included oral 1.0. Where the inductive effect is in- eluded, we adopt cir, . 0.2g. Throughout, we choose This means that, where overlap is included, the 7-1 overlap integral at = 0 is taken equal to the C-C overlap integral. These values are appropriate to a substituent which interacts rather strongly with the ring. In particular, it is considered to represent with reasonable accuracy the strength of the 7-1 IT-bond in N,N-dimethylaniline. We note that setting /00 = 1 (implying gi7 -/g at Q is 0) does not imply equality between the 7-1 and C-C 1r-bond strengths, because /9' is diminished in mag- nitude by the term involving MO electron repulsion integrals while gi7 does not contain a term of this type. Since in sub- stituted 'benzenes the 7-1 bonds are somewhat weaker than the bonds between ring carbon atoms, the adopted 7-1 overlap integral value may be viewed as an upper limit. In conformity with the above assumptions about the overlap integrals, we assume all bond lengths equal, and equal to the carbon-carbon bond length in benzene (1.4 h. For purely conjugative substituents, the MO Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA RDPR-Lninagprmo Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ?33? secular equation was solved by the method of Goodman and Shull, as described in Sec. 3. The inductive effect was treated by first-order perturbation theory,38 adopting the MO's .for the 38 H. Eyring, J. Walter, and G. E. Kimball, "Quantum Chemistry", Wiley and Sons, New York, 1944, p. 95. purely conjugative case as zeroth-order functions. All solutions were obtained subject to conditions (5) and (8). The results of the calculations are given in Tables 3 and 4. To illustrate an intermediate stage of calculation, the MO's and MO energies are given in Table 2. Bepzene -analogue Transitions:--The behavior of the Observed A .4A transition energies is on the borderline between Types ii and iii while the A --"B transition energies exhibit Type ii behavior (Fig. 4a). The trends predicted by the thdory with overlap neglected belong to Type i, and thus conflict with experi- ment. The inclusion of overlap leads to a better agreement with experiment, Type iii behavior being predicted for the A-4.A, and Type ii for the A B transition energies (Fig. )+b). Actually, the predicted trends tend to be too much like Type iii. However, we have probably overestimated the 7-1 overlap integral in adopting Po = 1, and a smaller estimate of the 7-1 overlap integral at G= 0 would lead to an improved agreement with ob- servation. In comparing the calculated and observed trends in transition energies, it should be kept in mind that, in the transition, the error incurred through neglect of overlap tends to be cancelled out by the Hamiltonian approximation inherent In the MO method.28 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13 ? CIA-RDP81 nin4npnn9qnnnAnnr,r, Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -34- The highest-energy absorption shows a definite red shift in the series I, IV, VI. It is natural to expect that, if the observations were extended to VII, the absorption energy would revert approximately to that for the corresponding ab- sorption in benzene. The implied non-monotonic behavior is correctly predicted by the theory with overlap included, according to which both the 5 -.2 and S a transition energies pass through minima at intermediate values of O. The theory predicts deviations from monotonic behavior for the other band ener- gies, but these are relatively slight and are not observed experimentally. We draw attention to the predicted 0-dependence of the lowest-energy singlet-triplet transition energy given in Table 3. In order to carry out the calculation, the hiu state In benzene was assumed to lie at 4.8 e.v., and the lowest- energy triplet state was assumed to be Bia (3.8 e.v.). Generally speaking, the trends in corresponding singlet-singlet transi- tions under intramolecular twisting. However, in each case some A differences are expected because of the changed magnitudes of the relevant CI integral. The parallelism between the calcu- lated variations of corresponding triplet and singlet state energies is not greatly disturbed either by the inclusion of overlap or by the choice of different limiting values for the benzene 3E state energy. la As far as transition energies are concerned, qualitative conclusions drawn from the calculations for a purely conjuga- tive substituent are not altered by inclusion of-the inductive effect. Declassified in Part - Sanitized Copy Approved for Release @P-Yr 2013/09/13 CIA RDP81 ni nLVIRnn9'-4nnflAnrInn Declassified in Part- Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 _31f... The highest-energy absorption shows a definite red shift in the series I, IV, VI. It is natural to expect that, if the observations were extended to VII, the absorptiOn energy would revert approximately to that for the corresponding ab- sorption in benzene. The implied non-monotonic behavior is correctly predicted by the theory with overlap included, aCCording to which both the 6 -4.2 and 6 transition energies pass through minima at intermediate values of 0. The theory predicts deviations from monotonic behavior for the other band ener- gies, but these are relatively slight and are not observed experimentally. We draw attention to the predicted 0-dependence of the lowest-energy singlet-triplet transition energy given in Table 3. In order to carry out the calculation, the 3Ela state In benzene was assumed to lie at 4.8 e.v., and the lowest- energy triplet state was assumed to be 3B1a (3.8 e.v.). Generally speaking, the trends in corresponding singlet-singlet transi- tions under intramolecular twisting. However, in each case some differences are expected because of the changed magnitudes of the relevant CI integral. The parallelism between the calcu- lated variations of corresponding triplet and singlet state energies is not greatly disturbed eitherby the inclusion of overlap or by the choice of different limiting values for the benzene 3E1a state energy. As far as transition energies are concerned, qualitative conclusions drawn from the calculations for a purely conjuga- tive substituent are not altered by inclusion of the inductive effect. Declassified in Part - Sanitized Copy Approved for Release @2-Yr 2013/09/13 CIA RDP81 011VVIPnnO'2rInf 1 A nnnn n Declassified in Part - Sanitized Co .y Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? ? -35.. The trends in the observed band intensities are shown, in Fig. 5, in indirect comparison with those predicted theoreti- cally. As predicted, the 6 1 and 5 .451 transition intensities decrease upon twisting, while the 6 42 and S -0 a intensity sum is relatively insensitive to twisting perturbations. The fact that the 6-101 intensity in VII (9 = 1/2) is substantially greater than that of the Aig -frB2u transition in benzene may be attributed to the inductive effect of the sub - stituent. For the 6 -*1 transition, the accidental forbiddeness predicted at an intermediate twist angle cannot be discerned with certainty in the experimental results. However, the relationship between the observed transition intensities and energies, which is shown in Fig. 6a, indicates indirectly that it does occur in fact (see below). The theory fails to account for the high intensity of the S-01 transition at small twist angles. With overlap neglected, the calculated oscillator strength (9 = 0) is less than half that observed in the spectrum of I, and a still smaller intensity is predicted with overlap included.39 In agreement with observation, 39 The condition of "accidental forkiddeness", which was mentioned in Sect 5 with reference to the "6 1 transition, is approached closely with the present set of parameters. This is a fortuitous circumstance, however, and is not an essential implication of the theory as applied here. To illustrate this, we .point out that ? the consideration of the inductive effect, with overlap included, could lead to a considerable increase of the predicted intensity. the observed intensities in the series I, II(b), III, IV, V, VI are related linearly to the corresponding transition energies (Fig. 6a). The points for II(a) and II(c) depart somewhat from Declassified in Part- Sanitized Co.y Approved for Release ? 50-Yr 2013/09/13 ? CIA RDPRi nindqPnno (-Inn Arw-wv-, Declassified in Part- Sanitized Copy Approved for Release ? 50-Yr 2013/09/13 : CIA-RDP81-01043R002300040009-9 -36- the main trend, while the point for VII lies well above the straight line passing through the points for I and V. The shapes of the corresponding theoretical curves are shown in Fig. 6b. At low energies, the observed linear relationship is reproduced in all three curves. This comes about from the approximate cos2 9 dependence of both the intensity and exci- tation energy for small and moderate 9 values. For larger twist angles the intensity, in particular, deviates markedly from Cos2 9 behavior. At higher energies, the observed behavior appears to conform qualitatively to that predicted with the Inductive effect included. The probable trend followed by the experimental points, including that for VII, is indicated by the broken line in Fig. 6a. From the figure, it is seen that the available information definitely suggests that the intensity of the ? -1,01 transition should pass through a minimum value at an intermediate value of 9, as predicted theoretically. We note that the data for II(a), II(b) and II(c) implies that the nitrogen - atom valence states for those molecules may be different from the unbridged cases. The Oscillator Strength Sum: --Klevene and Platt have pointed out that the sum of the oscillator strengths for the observed transitions decreases upon twisting, from 1.7 in I to 0.9 in VI. In qualitative accord with that result, the sum of squares of the transition moments listed in Table 5 decreases with increasing O. The predicted trend is not' so pronounced as that observed. However, the agreement between theory and experiment would be improved by taking more :transition moments Declassified in Part - Sanitized Copy Approved for Release @2-Yr 2013/09/13 CIA RDP81 011VVIPnnO'2rInf 1 A nnnn n Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 -37- into account, and by allowing appropriately for changes in the transition energies. previous Worl?--The theory of twisting effects on the spectra of ortho-substituted N,N-dimethylanilines has been discussed recently by MUrrell.40 Although MUrrell's method of 40 J. W. Murrell, J. Chem. Soc. ?1956, 3779. treatment is quite different from that adopted in the present work, it is gratifying that his conclusions are almost identical with some of those of the present study. Acknowledgments: - -We thank Professor M. Kasha for pro- viding the opportunity to undertake this study. We thank Professors M. Kasha and H. Shull for many helpful discussions; and Dr. P. 0. Lowdin for some helpful suggestions, which have been followed in this paper. Declassified in Part - Sanitized Copy Approved for Release 50-Yr 2013/09/13 ? CIA-RDP81-01043R007?Innn4nnna a 4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 - Table 1 EMPIRICAL PARAMETERS Overlap Approximation Excited State ,(e.v.) CI Integral Overlap Neglected Overlap Included 1A 1B 3A 1A 1B 3A -3.30 -2.98 -2.15 -3.09 -2.79 -2.02 0.121e 0.353, 0.233/ 0.129p 0.377fg 0.21+8 le Declassified in Part - Sanitized Copy Approved for Release . 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Table 2 MO% AID NO ElIERGY WITS? (*) I Overlap neglected aio - atm ail a12 a13 a aio Overlap included ais ail' ai2 ai3 ni 0 30 -60 90 0 0.7219 :.0.6748 1 .0.1501 2 .0.0280 0 0.7706 ? -0.6227 1 -0.1332 2 .0.0217 0 0.9127 $ -0.4021 1 -0.0731 2 -0.0076 0 1 s 0 1 0 2 0 0.6264 0.5490 0.4929 0.2146 0.5852 0.6123 0.040 0.1899 0.3930 0.8162 0.4038 0.1135 0 1 i) 0 0.2671 0.4747 -0.8363 .0.0582 0.2307 0.4615 -0.8510 -.0.0433 0.0367 0.023 -0.9093 -0.0162 0 0 , 1 0 0.1078 0.1188 0.1714 .0.9694 0.0895 0.1155 0.1411 -0.9777 0.0196 0.0912 0.0623 .0.9931 0 0 0 1 0.0588 04611 0.0756 0.1005 0.0485 0.0593 0.0630 0.0743 0.0196 0.0464 0.0287 0.0240 0 0 0 0 2.3543 1.6678 0.6597 -1.1278 2.2685 1.6523 0.7156 -1.0971 2.0879 1.5856 0.8718 -1.0330 -1.0000 1.0000 1.50000 1.0000 0.7027 .0.6857 .,0.1982 .0:11548 0.7605 -0.6262 .0.1799 ?0.0429 0.9185 .0.3814 -.0.1107 .0.0153 1 0 0 1 0.5554 0.4937 0.5733 0.3483 0.5188 0.5564 0.5751 0.3103 0.3367 0.7580 0.5300 0.1873 0 1 0 0 0.2570 0.4979 .0.8306 -0.1033 C).2238 0.5056 .0.8362 .0.0811 0.0996 0.4864 -0.8698 .0.0296 0 0 1 0 0.0819 0.0935 0.1845 -0.9820 0.0682 0.0921 0.1541 .0.9880 0.0272 0.0757 0.07735 -0.9970 0 0 0 1 0.0389 0.0392 0.0648 0.1223 0.0302 0.0385 0.0550 0.0899 0.0119 0.0313 0.0273 0.0283 0 0 0 0 1.4%1 1.1631 0.4870 -1.6683 1.4584 1.1506 0.5335 -1.5865 1.3734 1.0925 0.6690 -1.4181 1.3333 1.0000 0.8000 -1.3333 (a) Inductive effect neglected. 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Table 3 CALCULATED TRANSITION ENERGIES AND INTENSITIES Upper Overlap neglected Overlap neglected Overlap included State Inductive effect neglected Inductive effect included Inductive effect neglected E(e.v.) f 3A, 3.61 - 1- 4.53 0.041 0 1 5.77 0.139 2 6.73 0.447 2 6.73 0.537 3A 3.64 - 11 4.63 0.028 30 1 5.84 0.109 2 6.71 0.472 2 6.75 0.548 3A 3.74 - 11 4.83 0.004 60 1 6.05 0.029 2 6.79 0.597 2 6.84 0.590 3A1 3.80 1 4.90 o 90 1 6.20 0 2 7.00 0.600 2 7.00 0.600 E(e.v.) f 3.54 - 4.6o 0.018 .5.65 0.156 6.54 0.468 6.71 0.507 3.58 - 4.69 0.008 5.73 0.130 6.54 0.491 6.72 0.516 3.70 - 4.83 0.002 5.97 0.046 6.68 0.528 6.80 0.558 3.80 - 4;86 0.012 6.20 0 6.03 0.581 7.00 0.600 E(d.v.) f 3.91 - 4.74 0.058 6.31 0.022 7.23 0.462 6.96 0.769 3.86 - 4.8o 0.041 6.25 0.014 7.06 . 0.486 6.91 0.743 3.82 _ 4.93 0.006 6.18 0.014 6.84 0.547 6.88 0.646 3.80 - 14.90 o 6.20 o 7.00 0.600 7.00 0.600 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Overlap neglected G (?) ' Inductive effect neglected AA (0) AB (0) Table 4 STATE FUNCTIONS Overlap neglected Inductive effect included "A (o) A B (0) Overlap included Inductive effect neglected AA (0) AB (?) 24.0 19.7 26.3 14.8 -3.0 30 21.3 16.7 24.5 10.7 1.8 .60 11.7 7.1 10.5 -0.2 5.8 90 0 0 Oa -8.o 0 23.3 20.0 9.2 0 , (a) Higher order approximations than first-order perturbation theory will cause 11A to be . slightly different from zero in the presence of an inductive perturbation. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Declassified in Part - Sanitized Cop Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 ? 0(0) 1,41 0 .007 30 .003 60 .016 90 0 ? Table 5 a-c TRANSITION MOMENTS .937 .944 .966 1.0000 Ml141 Ml m, m53 .2 m13 .095 1.095 .383 .239 .166 2.32 .078 1.078 .382 .198 .162 2.27 .029 1.029 .334 .062 .128 2.12 0 1.000 0 0 0 2.00 (a) Both overlap and inductive effect neglected. (b) The magnitudes of the transition moments are given in units of ER, where denotes the electronic charge and R denotes the C-C bond length. The m's denote one-configuration transition moments, and denotes the sum of squares of the transition moments in columns 2-8. (c) The following were found to be less than 0.1 CR at 9 = 0: 12282r m029 m02. Declassified in Part - Sanitized Cop Approved for Release ? 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-q Declassified in Part - Sanitized Copy Approved for Release 0.; 50-Yr 2013/09/13: CIA-RDP81-01043R002300040009-9 Table 6 SPECTRA OF N,N-DIMETBYLANILINE AND RELATED MOLECULESa Substance Emaxx10-3 Eobs(e.v.) E (e.v.)b f sum corr I. N,N-Dimethylaniline ha. N-Metbylindoline b. N-Methyl-homo-tetrahydro- quinoline c. Troger's Base III. o -Chloro-NIN -dimethylaniline IV. N,N-Dimethy1-2-toluidine V. 2-Isopropyl -N,N -dimethylaniline 2,6-NIN-Tetramethylaniline VII. Benzoquinuclidine 2.39 15.50 22.2 36.6 2.9 10.0 2.0 8.5 2 x 1.11 2 x 4.25 1.8 7.6 18.5 36.10 1.30 6.36 3.1.4 30.8 1.17 4.30 (12.0) 2.09 8.6 36.1 0.5 (0.4) Declassified in Part - Sanitized Copy Approved for Release 0.036 0.29 0.54 0.79 0.041 0.21 0.021 0.17 2 x 0.017 2 x 0.08 0.026 0.14 0.39 0.72 0.014 0.128 0.23 0.69 0.013 0.089 I= NO ? (