Perylene Complexes Research Articles

The First Perylene Complexes of Neodymium and Dysprosium

Neodymium and dysprosium perylene complexes LnI(Per)(DME)2⋅Per (Ln = Nd, Dy) were obtained for the first time by the reaction of the Ln diiodides with perylene in dimethoxyethane. The structure of dysprosium complex was established by X-ray diffraction (CCDC no. 2184200). Experimental–theoretical electron density analysis was performed to specify the type of coordination between the dysprosium cation and perylene in DyI(Per)(DME)2⋅Per. Despite the identical composition, the Nd and Dy complexes have different structures, which is reflected in their luminescence properties.

GEOCHEMICAL CHARACTERISTICS OF THE ORGANIC MATTER OF THE RIPHEAN DEPOSITS OF THE UST’-MAYSKAYA PARAMETRIC WELL FOR ASSESSMENT OF THE OIL AND GAS POTENTIAL

The investigation of the dispersed organic matter of the rocks in the Ust’-Maiskaya wildcat area was conducted. Data on the features of dispersed organic matter composition in the range of 2868.731-3057.68 m are presented. Alkanes, mono-, bi-, tri-, tetra- and pentacyclic arenes, bi-, tri-, tetra- and pentacyclanes, tetracyclic naphthenoaromatic hydrocarbons, dibenzothiophenes have been identified among hydrocarbons studied by means of gas chromatography - mass-spectrometry. Perylene and traces of nickel metalloporphyrins and perylene were also determined by means of spectrophotometry. It is shown that the initial organic matter was formed under the conditions of reduction and suboxidation, with a significant contribution from both terrestrial vegetation and phytoplankton. The presence of nickel porphyrin and perylene complexes in some sections of the log suggests the shallowness of the sedimentation basin and the proximity of the coastline during OM accumulation. The calculated vitrinite reflectance indicates that the differences observed for the MK2 stage of catagenesis correspond to the main zone of oil generation.

1 : 2 charge-transfer complexes of perylene and coronene with perylene diimide, and the ambipolar transistors

The title 1 : 2 charge-transfer complexes have DAA-type mixed stacks and show electron-dominant ambipolar transistor properties.

New Advanced Hybrid Organic–Inorganic Complex

New hybrid organic–inorganic complexes of perylene with nanodiamonds were developed and fabricated. The fact of complex formation was confirmed by the analysis of the infra-red (IR) absorption spectra and their spectral-luminescent properties. It was shown as a result of nanodiamond (ND) template synthesis that in new complexes based on NDs occur appearance of strong structured excitation bands in the ultra violet (UV) region of spectrum, within 230–300 nm. The formation of new UV excitation centers in complexes leads to a significant enhancement of luminescence in the green region of the spectrum.

Highly Fluorescent Platinum(II) Organometallic Complexes of Perylene and Perylene Monoimide, with Pt σ-Bonded Directly to the Perylene Core

3-Bromoperylene (BrPer) or N-(2,5-di-tert-butylphenyl)-9-bromo-perylene-3,4-dicarboximide (BrPMI) react with [Pt(PEt(3))(4)] to yield trans-[PtR(PEt(3))(2)Br] (R = Per, 1a; R = PMI, 1b). Neutral and cationic perylenyl complexes containing a Pt(PEt(3))X group have been prepared from 1a,b by substitution of the Br ligand by a variety of other ligands (NCS, CN, NO(3), CN(t)Bu, PyMe). The X-ray structures of trans-[PtR(PEt(3))(2)X] (R = Per, X = NCS (2a); R = PMI, X = NO(3) (4b); R = Per, X = CN(t)Bu (5a)) show that the perylenyl fragment remains nearly planar and is arranged almost orthogonal to the coordination plane: The three molecules appear as individual entities in the solid state, with no π-π stacking of perylenyl rings. Each platinum complex exhibits fluorescence associated to the perylene or PMI fragments with emission quantum yields, in solution at room temperature, in the range 0.30-0.80 and emission lifetimes ∼4 ns, but with significantly different emission maxima, by influence of the X ligands on Pt. The similarity of the overall luminescence spectra of these metalated complexes with the perylene or PMI strongly suggests a perylene-dominated intraligand π-π*emissive state, metal-perturbed by interaction of the platinum fragment mostly via polarization of the Ar-Pt bond.

Structural Characterization of Aromatic−Aromatic Complexes by Rotational Coherence Spectroscopy

Rotational coherence spectroscopy (RCS) has been applied in structural studies of (a) aromatic−aromatic van der Waals complexes of the form M−X, where M = perylene or fluorene and X = benzene or toluene, and (b) aromatic−aliphatic hydrocarbon dimers of the form M−Y, where M is as above and Y = cyclohexane or methylcyclohexane. For all of the perylene complexes the experimentally determined rotational constants are found to be consistent with centrally bound, parallel-stacked structures in which the monomer planes are separated by a distance of 3.5−4.3 A. Analogous geometries also characterize the fluorene−aliphatic species. However, the two fluorene−aromatic complexes have structures that depart from the parallel-stacked form. Both species have slipped geometries in which the monomer planes are not directly over one another. And, in the case of fluorene−benzene, the two aromatic planes are tilted with respect to one another. These differences are attributed to the significant contribution of electrostatic forces in determining the fluorene−aromatic geometries.

Rotational Coherence Measurements and Structure Calculations of Hydrogen-Bonded Complexes of Perylene with Water and Alcohols

Rotational coherence spectroscopy has been used to measure the inertial properties of 1:1 complexes of perylene with water and several different aliphatic alcohols, under supersonic expansion condi...

Perylene complexes with p-dichlorobenzene and related species: comparison of rotational coherence data with structure calculations

Rotational coherence experiments have been carried out on complexes of perylene with p-dichlorobenzene (DCB), p-difluorobenzene (DFB) and hexafluorobenzene, largely to seek an explanation for the unusually small complexation shifts of the first two. All three complexes were found to have overlapped, parallel ring structures, similar to that of perylene/benzene. Moreover, in structures corresponding to the electronic ground state, the halogen-halogen axes of DFB and DCB were found to be aligned perpendicular to the perylene long axis.

Structural measurements of hydrogen-bonded complexes of perylene with water and methanol

Rotational coherence experiments have been carried out for 1:1 van der Waals complexes of perylene with water and methanol. The observed inertial properties are consistent with structures corresponding to potential-energy minima calculated via MM2 techniques. The results show that both types of complex involve hydrogen-bonding to π-electrons on the perimeter of the aromatic molecule.

Rotational Coherence Measurements of Perylene Complexes with Benzene and Naphthalene: Vibronic Excitation and Structural Relaxation

Rotational Coherence Measurements of Perylene Complexes with Benzene and Naphthalene: Vibronic Excitation and Structural Relaxation

Structures of perylene complexes with long-chain alkanes and alkyl halides examined by rotational coherence spectroscopy

Fluorescence excitation spectra of jet-cooled van der Waals complexes of the planar aromatic hydrocarbon perylene with the n-alkanes pentane, hexane, octane, and decane show in each case a single structural form. Rotational coherence transients observed for these species, spaced by 2.5–4.4 ns, are consistent with the n-alkane chain oriented parallel to the long axis of perylene and placed 3.6 Å above its surface. In contrast, the 1-chloropentane and 1-fluoropentane complexes of perylene both exhibit three conformational isomers (α,β,γ) in the electronic ground state. Rotational coherence experiments have measured the structures of these different species in the S1 state, via 000 excitation, proving the existence of three distinct isomers in each case. Dispersed emission spectra following vibronic excitation at 355 cm−1 (A10) indicate in each case that the γ structure relaxes to the α form. Knowledge of the structures of the different forms provides a basis to identify the photoisomerization trajectories. Rotational coherence spectroscopy (RCS) was also used to examine the structures following vibronic excitation. The n-alkane complexes each revealed at least one prominent recurrence transient, showing that vibronic excitation and subsequent vibrational redistribution processes do not necessarily cause rapid rotational dephasing. Similarly, an appreciable degree of rotational coherence persisted into the nanosecond domain for the α and β isomers of the fluoropentane and chloropentane complexes. On the other hand, loss of the γ form was confirmed via the RCS traces, since there were no recurrences for 355 cm−1 excitation. In this way, RCS measurements following vibronic excitation can provide a means to probe conformational stability.

Vibrational relaxation of isomerizing alkyl halide complexes of perylene measured by stimulated emission spectroscopy

Experiments involving picosecond stimulated-emission spectroscopy have monitored the resonance emission following vibronic excitation of the 1:1 complexes ofperylene with n-hexane, n-octane and the three isomers each with 1-chlorobutane and 1-chloropentane. The experiments confirm that photoisomerization is occurring in the alkyl halide complexes, by labelling the transient resonant emission. The rates of vibrational relaxation (IVR) at 355 cm −1 excess energy differ by up to a factor of three for different isomers, and are independent ofisomeric stability.

Photoisomerization of molecular van der Waals aggregates. Structural assignments of isomeric forms of 1-chlorobutane/perylene via rotational coherence spectroscopy

Van der Waals complexes of perylene with 1-chlorobutane, prepared under supersonic jet conditions, exist in three distinct isomeric forms distinguishable by their spectral red-shifts of 265,238 and 184 cm −1. Following vibronic excitation at 355 cm −1, two of these isomers yield similarly shaped and broadened fluorescence bands of ≈ 180 cm −1 width, suggesting a rapid isomerization. A third isomer is not coupled, showing a distinct spectrum even for a vibrational energy of 700 cm −1. Structure determinations of all three isomers are reported using rotational coherence spectroscopy. The existence is demonstrated of three remarkably different binding sites for 1-chlorobutane on the perylene surface.

Polarized luminescence and structure of Van der Waals complexes of organic molecules

We consider the possibility of identifying the structure of Van der Waals complexes formed by jet-cooling by their luminescence polarization. This possibility is confirmed by the example of perylene complexes with noble gases in comparison with independent data, and structure identifying of such complexes with 1,4-dioxyantraquinone is carried out. The conditions of the optimum efficiency of the method are discussed.

Activated barrier crossing in van der Waals complexes of perylene with alkyl halides

ADVERTISEMENT RETURN TO ISSUEPREVArticleNEXTActivated barrier crossing in van der Waals complexes of perylene with alkyl halidesAndrea L. Motyka, Stacey A. Wittmeyer, R. Jefferson Babbitt, and Michael R. ToppCite this: J. Phys. Chem. 1989, 93, 17, 6322–6329Publication Date (Print):August 1, 1989Publication History Published online1 May 2002Published inissue 1 August 1989https://doi.org/10.1021/j100354a012RIGHTS & PERMISSIONSArticle Views37Altmetric-Citations10LEARN ABOUT THESE METRICSArticle Views are the COUNTER-compliant sum of full text article downloads since November 2008 (both PDF and HTML) across all institutions and individuals. These metrics are regularly updated to reflect usage leading up to the last few days.Citations are the number of other articles citing this article, calculated by Crossref and updated daily. Find more information about Crossref citation counts.The Altmetric Attention Score is a quantitative measure of the attention that a research article has received online. Clicking on the donut icon will load a page at altmetric.com with additional details about the score and the social media presence for the given article. Find more information on the Altmetric Attention Score and how the score is calculated. Share Add toView InAdd Full Text with ReferenceAdd Description ExportRISCitationCitation and abstractCitation and referencesMore Options Share onFacebookTwitterWechatLinked InReddit PDF (988 KB) Get e-Alerts

Time-resolved desorption of argon and methane from the surface of a perylene molecule

Time-resolved fluorescence measurements have been made of the predissociation of van der Waals complexes of perylene with Ar and CH 4. At 705 cm −1, predissociation of Ar 1,2 complexes occurs in competition with efficient singlet-triplet coupling. At 900 cm −1, both Ar and CH 4 complexes show little contribution from singlet-triplet coupling. The predissociation of CH 4 complexes at this energy is very rapid, largely as a result of extensive vibrational coupling.

Weak vibrational coupling in a large van der Waals complex: Fluorescence spectroscopy of perylene/naphthalene

Fluorescence excitation and dispersed fluorescence spectra are reported for 1:1 and 2:1 complexes of naphthalene with perylene under supersonic jet conditions. Confirming preliminary results, the fluorescence spectra of the 1:1 complex following excitation of an ag (in-plane) mode at 353 cm−1 and its first overtone show unusually weak vibrational coupling. Although excitation of combination levels of 3531 with out-of-plane modes at 74, 79, and 93 cm−1 gives rise to emission which is predominantly ‘‘relaxed,’’ the residual ‘‘unrelaxed’’ component indicates a significant degree of mode-selective vibrational coupling. It is notable that the vibrational coupling for 3532 excitation (i.e., at ≈700 cm−1) is substantially less extensive than for excitation into the 3531 combination bands nearly 300 cm−1 lower in energy. A similar comparison has been made between a second ag mode, at 550 cm−1, and a perturbed b3g (out-of-plane) mode, at 540 cm−1. In this case, the data indicate a difference in coupling, which is less obvious than for the 353 cm−1 case, but still indicates a significant dynamic difference in the picosecond domain. Higher-energy excitation is seen to give rise to a large amount of spectral broadening, to ≈700 cm−1, yet without any appreciable shift. This indicates that a single equilibrium conformation is present. Comparison with data for uncomplexed perylene and for other perylene complexes at a similar excitation energy (1300–1400 cm−1) suggests that the broadening is due to vibrational coupling involving combinations and overtones of Franck–Condon active low-frequency modes in perylene/naphthalene. Fluorescence excitation data for 2:1 complexes show that the three-band combination of the 1:1 complex at 74–93 cm−1 is replaced by a single, strongly Franck–Condon active mode at 62 cm−1. The corresponding ground state frequency is about 56 cm−1 and, overall, this mode shows harmonic behavior. Like the 1:1 complex, the fluorescence spectrum following excitation into v=2 of the out-of-plane mode, at ≈125 cm−1, shows little evidence of vibrational coupling. At and above 353 cm−1, perylene/(naphthalene)2 shows extensive vibrational coupling, since no structure persists in the fluorescence spectra. A comparison has been made between the naphthalene and some other 1:1 complexes of perylene. At 353 cm−1, the Ar1 complex shows less vibrational coupling than perylene/naphthalene, although the presence even of an argon dimer generates a greater degree of coupling. The benzene complex shows extensive IVR at this energy, by comparison with the weakly coupled naphthalene case. Further, while the naphthalene/perylene out-of-plane modes show predominantly resonant Franck–Condon emission profiles, up to excitation energies of 170 and 124 cm−1 for the 1:1 and 2:1 complexes, respectively, perylene/benzene shows extensive IVR even for 70 cm−1 excitation. These data strongly indicate that intermolecular modes, especially weakly hindered internal rotation, are responsible for the pronounced differences in the degree of vibrational coupling.

Jet spectroscopy of perylene complexes: Comparisons of TMS, carbon dioxide, ethylene and butadiene

The fluorescence excitation spectra are reported for van der Waals complexes of perylene with tetramethylsilane (TMS), 1,3-butadiene, ethylene and CO 2. The 1:1 complexes with TMS, ethylene and butadiene have simple spectra, and the spectral red shifts are predictable from solvent-shift theory, while the CO 2 complexes are shown to exhibit anomalously small red shifts and extended low-frequency mode progressions. Dispersed fluorescence of the assigned 1:1 CO 2 complexes is consistent with the excitation spectrum, indicating a substantial difference in the equilibrium conformation of the complex between the two electronic states of the host molecule. Potential energy calculations using a point coulombic charge correction predict a non-center-of-mass geometry for CO 2 complexes, consistently with the observed spectra. Calculations of the binding energies are shown to be in satisfactory agreement with experimental data (1250, 1295–1398 and 2300–2580 cm −1 for CO 2, C 2H 4 and C 4H 6, respectively). At the 2:1 complexation level, while butadiene and TMS appear to form the expected trans conformers, the ethylene and CO 2 complexation spectra indicate the presence of guest molecule aggregates. In these cases, guest-guest interactions are evidently competing with the usually dominant process of molecular adsorption onto the host species.

Jet spectroscopy of pyrene complexes: Unusual complexation shifts in the S 0 → S 1 spectrum

The fluorescence excitation spectra of pyrene complexes with n-alkanes are reported for the S 0 → S 1 and S 0 → S 2 transitions. The S 2 spectral shifts are predictable from theory, and by comparison with other molecules, such as perylene. On the other hand, the S 1 Resonances of pyrene complexes show unusually small displacements from those of the parent species. The spectra of the butane, pentane and hexane complexes actually exhibit net blue shifts. This behaviour provides good evidence for a repulsive interaction in the S 1 state, which is not observed in S 2. Moreover, because the butadiene and benzene complexes give predictable red shifts ⩾ 100 cm −1, and these are found to have plane-parallel geometries, the blue shift correlates with a host carbon—guest hydrogen interaction in the repulsive regime. We also report that the ethylene complex of pyrene exhibits a net blue shift on the S 0 → S 1 transition, and a red shift on S 0 → S 2 only 75% of the predicted value, based on measurements with perylene complexes. This behaviour strongly indicates that ethylene-pyrene has a T-shaped configuration, as predicted by potential energy calculations.

Perylene-naphthalene: restricted IVR in a strongly bound van der waals molecule

The study of the spectroscopic properties of molecular complexes of perylene has been extended to naphthalene. Calculations extrapolated from earlier work predict a deviation from center-of-mass, parallel-plane geometry, and this prediction is supported by the experimental data. The complexes show a very large red-shift, of 748 cm −1, which is almost twice that of benzene. A 2 : 1 complex was also observed, exhibiting a nearly harmonic shift, to 1443 cm −1. The spectra show little perturbation of the in-plane modes from the free perylene case, but strong new low-frequency bands are seen, which may be attributed to complexation-induced deformation of the perylene ground state. The most important result is that strong resonance fluorescence, which was suppressed in small molecule complexes of perylene, is observed for the perylene-naphthalene 353 cm −1 in- plane mode. By contrast, excitation into combinations of out-of-plane deformation modes in the same energy region effectively eliminated the resonance fluorescence. This is, therefore, an important case where a mode of a big molecule is decoupled from the quasi-continuum, and develops small-molecule character.