On the first electronic transitions in molecular spectra of conjugated diphenylpolyenes: A reappraisal

2022

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In this work, we present absorption, emission, and excitation of emission spectra of all‐trans‐DPH obtained in solution between 77 and 363 K. The analysis of these spectra allows to evaluate that this molecular probe, widely used in biophysics, does not isomerizes in solution to s‐cis‐DPH at the temperatures explored. These results are in contradiction to those reported by previous studies that emphasize that (a) all‐trans‐DPH isomerizes to s‐cis‐DPH when dissolved and the temperature ranges from 283 to 373 K and (b) the molar fraction of s‐cis‐conformer equals, or even exceeds, the molar fraction of the all‐trans‐conformer at the highest temperature studied. In this work, we show how we can infer the changes taking place in the molecular structure of DPH looking at the wavenumber (ν) shift of the peaks on the absorption and emission spectra as a function of temperature. The analysis of these band shifts allows us to corroborate the change, determined by Ogawa et al. by X‐ray diffraction, that occurs in the structure of DPH in the crystalline phase through a bicycle pedal process with temperature.

Section: Resultsmentioning

confidence: 99%

On the temperature‐dependent isomerization of all‐trans‐1,6‐diphenyl‐1,3,5‐hexatriene in solution: A reappraisal

2022

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“…As have reported in recent works, [ 13,16–18 ] the Stokes shift presented by diphenylpolyenes will disappear if these compounds adopt an adequate molecular structure. In the molecules that adopt this molecular structure, the origins of the first absorption band and of the emission of the compound practically overlap.…”

Section: Resultsmentioning

confidence: 66%

“…In recent years, our laboratory has provided photophysical evidence of diphenylpolyenes, [ 12–18 ] which has left unsubstantiated the main arguments by Hudson and Kohler based on the existence of an underlying phantom state 2 1 Ag, which hypothetically controls the emission of these compounds. Our contributions lead inexorably to a photophysical model based on structural changes that starts under normal conditions with the excitation of a molecular structure of the non‐plane polyene compound [ 16,18 ] that generates the detected SS. This starting point of the photophysics of these compounds is undoubtedly novel based on the previous reasoning presented by other authors.…”

Section: Introductionmentioning

confidence: 99%

Carbon disulfide solvent, helping to clarify the Stokes shift in diphenylpolyenes

2020

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The Stokes shift found by Hausser et al. in diphenylpolyenes, which increases by lengthening its polyene chain, has received in the last 80 years a series of explanations, which we believe are not satisfactory. In this current work, using of CS2 as solvent for the fluorescence measurements of 1,6‐diphenylhexatriene (DPH) and 1,8‐diphenyloctatetraene (DPO) against temperature, it is concluded that the Stokes shift, shown by the diphenylpolyenes, is of structural origin and that it disappears from its photophysical behavior if it is possible that these compounds in their ground electronic state adopt a planar molecular structure, from which to initiate their photophysics.

“…This information together with other evidence provided in recent years by our laboratory [ 1,2,11–16 ] allows us to draw the following conclusions in order to propose an adequate model to correctly interpret the photophysics of polyene compounds: The position of the first intense peak in the excitation spectrum of the DPO in the six n ‐alkanes used represents a bathochromism that varies linearly with the temperature from 293 to the melting point temperature of the corresponding alkane. This behavior is red‐shifted in parallel fashion as the alkane chain is lengthened, as a result of the alkane's increasing polarizability on lengthening of its chain.The reported increase of the bathochromism with the decrease of the temperature undoubtedly also includes a structural contribution because the phenyl groups in the diphenyl polyenes in liquid solvents present such a small torsion barrier what makes their two phenyl groups are continuously rotating out of the coplanar situation.…”

Section: Discussionmentioning

confidence: 86%

“…This behavior is red‐shifted in parallel fashion as the alkane chain is lengthened, as a result of the alkane's increasing polarizability on lengthening of its chain.The reported increase of the bathochromism with the decrease of the temperature undoubtedly also includes a structural contribution because the phenyl groups in the diphenyl polyenes in liquid solvents present such a small torsion barrier what makes their two phenyl groups are continuously rotating out of the coplanar situation. [ 11,17 ] Consequently, the aforementioned bathrochromic increase will be the result of two contributions, one generated by the increase in the polarizability of the solvent and the other due to the decrease in the torsion of its phenyl groups that will adopt an average conformation closer to a coplanar with decreasing temperatures. Consequently, the absorption spectrum and also the excitation spectrum in these solutions must be produced contrary to what is commonly accepted [ 18 ] for light absorbing structures of a noncoplanar DPO. b)At temperatures below their melting points, the DPO solutions in these alkanes barely change the position of the discussed peak.…”

Section: Discussionmentioning

confidence: 99%

On the photophysics of a polyene dissolved in n‐alkanes when the temperature drops from 293 to 77 K

2020

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