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Perylene

Perylene is a (PAH) with the molecular formula C₂₀H₁₂, consisting of five ortho- and peri-fused rings arranged in a planar structure, often described as dibenzo[de,kl]. It appears as a to powder or crystalline solid with a molecular weight of 252.31 g/mol and a of 276–279 °C. Perylene exhibits strong properties, with at approximately 400 nm and at 445 nm in acetonitrile-water mixtures, making it highly photostable and suitable as a hydrophobic fluorescent probe for spectroscopic studies. First synthesized in the early , perylene and its derivatives, particularly perylenediimides (PDIs), have been historically significant as vibrant, lightfast and pigments for textiles, paints, and lacquers since their introduction around 1913. In modern applications, perylene serves as a core scaffold for in , including organic field-effect transistors (OFETs), organic light-emitting diodes (OLEDs), and dye-sensitized solar cells, due to its excellent charge transport and semiconducting characteristics. Additionally, its derivatives are increasingly utilized in for bioimaging, photothermal therapy, and , leveraging their near-unity quantum yields, high extinction coefficients (around 10⁴ M⁻¹ cm⁻¹), and tunable near-infrared absorption for cancer theranostics and cellular staining. Perylene also functions as a standard for detecting PAHs in environmental samples, such as river sediments.

Structure and Properties

Molecular Structure

Perylene is a with the C20H12 and a of 252.31 g/. Its is perylene, while the systematic name is dibenzo[de,kl]. The molecule consists of an ortho- and peri-fused system of five benzene rings, forming a rigid, extended aromatic framework. This architecture can also be conceptualized as two units connected by a central C-C bond at the 1 and 8 positions of each naphthalene. All 20 carbon atoms in perylene are sp² hybridized, contributing to its characteristic planar geometry and delocalized π-electron system typical of polycyclic aromatic hydrocarbons. The 12 hydrogen atoms are attached to the peripheral carbons, completing the structure without introducing steric distortions in the core. This planarity facilitates efficient π-overlap across the rings, underpinning its aromatic stability. X-ray crystallographic analysis confirms the molecular planarity of perylene, with only minor deviations attributable to intermolecular interactions in the solid state. Key bond length measurements reveal variations consistent with partial bond order alternation: the central peri-bond linking the naphthalene units measures 1.471 ± 0.006 Å, longer than typical aromatic C-C bonds (around 1.39 Å) but indicative of a single-bond character within the conjugated system. Peripheral bonds show shorter lengths (approximately 1.36–1.42 Å), aligning with predictions from valence-bond and molecular-orbital theories. The crystal structure is monoclinic with space group P21/a and four molecules per unit cell, dimensions a = 11.277 Å, b = 10.826 Å, c = 10.263 Å, β = 100.55°.

Physical and Chemical Properties

Perylene is a brown solid at room temperature. It exhibits a melting point of 276–279 °C and sublimes in the range of 350–400 °C. The density of perylene is about 1.35 g/cm³. Perylene demonstrates low solubility in water, with a reported value of 0.0004 mg/L, reflecting its hydrophobic nature. It is freely soluble in organic solvents such as carbon disulfide and chloroform, and moderately soluble in benzene. As a non-polar polycyclic aromatic hydrocarbon (PAH), perylene exhibits high electron affinity, approximately 0.97 eV. Due to its extensive aromatic system, perylene possesses high thermal and ; its planar molecular structure enhances this robustness by facilitating delocalized π-electrons.

Synthesis

Laboratory Synthesis

Perylene was first synthesized in the laboratory by Roland Scholl in 1910 through the dehydrogenative coupling, known as the Scholl reaction, of using aluminum chloride (AlCl₃) as a Lewis acid catalyst at approximately 180 °C. This method involves the oxidative dimerization and cyclization of two naphthalene units, but suffered from extremely low yields due to extensive side reactions and decomposition products. The simplified reaction can be represented as: $2 \ce{C10H8} \rightarrow \ce{C20H12} + 2 \ce{H2} In 1913, Scholl refined the approach by employing 1,1'-binaphthyl as the precursor with AlCl₃ at 140 °C, which improved selectivity and yields, though still modest at around 20-30%. Iron(III) chloride (FeCl₃) can also serve as an oxidant in this variant, maintaining similar conditions. Typical yields for the Scholl reaction range from 20-50%, depending on the precursor purity and reaction setup, with purification often achieved via vacuum sublimation or column chromatography to isolate the yellow crystalline product. A classical alternative involves the thermal of at high temperatures near 800 °C under reduced pressure, where perylene forms via radical-mediated dimerization and dehydrogenation, albeit in low yields as part of a complex mixture of polycyclic aromatic hydrocarbons. This method highlights perylene's formation in high-temperature environments but is less selective for laboratory-scale preparation. Modern laboratory syntheses have focused on higher efficiency and purity. In 1968, of 1,1'-binaphthyl in the presence of dust at elevated temperatures provided perylene in up to 50% yield, offering a straightforward reductive dehydrogenation route suitable for small-scale production. More recently, in 2010, treatment of 1,1'-binaphthyl with alkali metals like in induced anionic cyclodehydrogenation, yielding perylene in nearly quantitative amounts under mild conditions, followed by and . Flash vacuum of 1,1'-binaphthyl at 900-1000 °C has also been employed for high-purity perylene, minimizing impurities through rapid vapor-phase reaction and condensation. These approaches prioritize controlled conditions to enhance yields and facilitate handling in research settings, with perylene typically purified by under high vacuum.

Industrial Production

Perylene is primarily obtained on an industrial scale as a of high-temperature processes applied to or heavy fractions, which occur during production and related operations. In , perylene constitutes approximately 0.25% of the composition, emerging alongside other polycyclic aromatic hydrocarbons (PAHs) in the distillate fractions. The separation of perylene begins with of the crude to isolate PAH-enriched streams, followed by targeted extraction techniques to concentrate the compound. Further purification to achieve >99% purity typically employs solvent extraction, zone refining, or vacuum sublimation, ensuring removal of impurities for use as a intermediate. These methods enhance yield and quality while addressing the challenges of handling complex PAH mixtures. Global production of perylene is limited, with a market value of approximately $325 million as of 2024, driven by demand for high-performance pigments and optoelectronic materials. Major producers include SE, Corporation, and Corporation, with significant manufacturing concentrated in and . Recent expansions, such as 's addition of up to 200 metric tons of perylene-based capacity in , , as of November 2025, reflect growing market needs. Production costs for perylene range from $500 to $1000 per kg, varying with purity levels and scale; technical-grade material is more economical, while high-purity variants incur premiums due to specialized purification and raw material sourcing. Environmental regulations on usage, stemming from PAH toxicity concerns, have prompted shifts toward alternative feedstocks and cleaner processes, including explorations of bio-based via to mitigate emissions. From 2020 to 2025, industry trends emphasize , with innovations in synthetic routes—such as optimized Scholl reactions from precursors and catalytic dehydrogenation methods—aiming to reduce reliance on traditional sources and improve efficiency. These developments support perylene's role in intermediates while aligning with stricter emission controls.

Reactions and Derivatives

Reduction and Oxidation Reactions

Perylene undergoes with alkali metals, such as sodium, in (THF) to form a stable and, upon further , a dianion. The exhibits a color, while the dianion is , reflecting their distinct electronic structures. These species are generated via one- and two-electron transfers, respectively, with the first approximately -1.68 V vs. in aprotic solvents. The key process for radical anion formation can be represented as: \text{C}_{20}\text{H}_{12} + e^- \rightarrow [\text{C}_{20}\text{H}_{12}]^{\bullet-} Characterization of these anions includes of diglyme-solvated salts, revealing solvent-separated ion pairs for s and contact ion pairs or chains for dianions depending on the cation. Electron spin resonance (ESR) spectra of the indicate delocalized spin density across the polycyclic framework. Recent (DFT) studies have further elucidated the stability of these anions, showing that effects and cation coordination significantly influence their geometric and electronic properties in . Oxidation of perylene is less common due to its high but occurs via electrophilic attack at the bay positions (e.g., 1,12- or 3,10-), leading to derivatives. For instance, oxidation yields 3,10-perylenediquinone as the major product (89–94% yield) through addition and dehydrogenation at these reactive sites. This contrasts with the more facile , highlighting perylene's preference for electron acceptance over donation in processes.

Key Derivatives

Perylene diimides (PDIs) represent one of the most prominent classes of perylene derivatives, synthesized through the imidation of perylenetetracarboxylic dianhydride (PTCDA) with primary amines such as aliphatic or aromatic amines. This typically occurs in high-boiling solvents like molten , yielding PDIs in high efficiency, often exceeding 90%, and forming the basis for numerous commercial dyes due to their robust π-conjugated structure and tunable via N-substitution. Perylene quinones, including key oxidation products like PTCDA, are derived from the aerial or chemical oxidation of perylene, introducing carbonyl groups at the 3,4,9,10-positions to form the tetracarboxylic dianhydride. This transformation enhances the electron-withdrawing character and planarity of the core, making PTCDA a versatile precursor for further derivatization in . Higher rylenes, such as terrylene and quaterrylene, extend the perylene framework through oxidative coupling reactions of perylene precursors, like 3-(1-naphthyl)perylene for terrylene via cyclodehydrogenation using oxidants such as FeCl3 or DDQ. These methods yield elongated chromophores with extended conjugation, enabling applications in advanced , though solubility challenges necessitate peripheral substitution. Quaterrylene synthesis follows analogous oxidative dimerization of bis-naphthyl perylenes, often mediated by Sc(OTf)3/DDQ systems. Recent advancements (2020–2025) have focused on water-soluble PDI variants for bioimaging and sensing, achieved through post-synthetic modifications like sulfonation or attachment via efficient coupling strategies, addressing the inherent hydrophobicity of the core while preserving properties.

Optical Properties

Absorption Characteristics

Perylene displays prominent UV-Vis bands in the visible region, primarily arising from π-π* within its extended polycyclic aromatic system. The lowest-energy corresponds to the symmetry-allowed S₀ → S₁ , characterized by a well-resolved vibrational progression dominated by C-C modes. A higher-energy, symmetry-forbidden S₀ → S₂ appears as a weaker band around 260 nm. In solution, the S₁ band exhibits strong maxima at 434 nm (ε = 38,500 M⁻¹ cm⁻¹) and a vibronic shoulder at 452 nm, reflecting the Franck-Condon envelope of the electronic . The absorption spectrum of perylene is moderately sensitive to solvent polarity, exhibiting a bathochromic shift of several nanometers upon transitioning from nonpolar solvents like (λ_max ≈ 436 nm) to polar ones such as . This positive solvatochromism arises from stabilization of the polar relative to the , though the effect is small due to perylene's nonpolar nature. In more polar environments, the S₁ band's intensity distribution may also subtly broaden. Time-dependent density functional theory (TD-DFT) calculations reproduce these features effectively, predicting a HOMO-LUMO gap of approximately 2.8 for the , consistent with the optical gap derived from the 434 nm onset. These computations highlight the dominant role of the HOMO → LUMO promotion in the S₁ state, with minor contributions from higher orbitals influencing the vibronic structure. In aggregated states, such as those encountered in thin films, perylene's absorption undergoes significant modification due to intermolecular interactions. Recent studies from the reveal the formation of J-aggregates in nanostructured perylene films, leading to narrowed, red-shifted bands (e.g., λ_max shifting to ~500 nm) with enhanced , as opposed to H-aggregates that blue-shift and weaken the spectrum. These effects, observed in vacuum-deposited or MOF-hosted films, underscore the material's potential for tuned in solid-state environments.

Emission and Fluorescence

Perylene displays intense blue upon photoexcitation, with an maximum typically observed between 450 and 470 in nonpolar solvents such as or . This arises from the radiative decay of the singlet excited state, characteristic of its rigid polycyclic aromatic structure. The (φ) reaches approximately 0.95 in deoxygenated environments, reflecting near-unity efficiency under conditions that minimize non-radiative pathways. The excited-state lifetime of perylene fluorescence spans 5-10 in , depending on and , with values around 4-5 commonly reported in hydrocarbons. A modest of approximately 20-30 nm separates the emission peak from the onset, enabling efficient in donor-acceptor systems while minimizing self-. Perylene's emission is sensitive to its microenvironment; oxygen acts as an efficient quencher through collisional and charge-transfer interactions, significantly reducing the in aerated solutions. In contrast, rigid media such as matrices or crystalline forms suppress vibrational relaxation and enhance emission intensity and lifetime, often exceeding 10 . These properties position perylene as a for blue-emitting organic light-emitting diodes (OLEDs), where its high efficiency contributes to device in the visible range. Recent advancements in perylene (PDI) derivatives, achieved through bay- , have extended into the near-infrared (near-IR) , with peaks beyond 800 nm reported in 2024 studies on twisted or extended chromophores. Such modifications introduce bathochromic shifts while preserving reasonable quantum yields, opening avenues for bioimaging and .

Applications

Dyes and Pigments

Perylene diimides (PDIs) serve as the primary basis for high-performance pigments in the colorant industry, offering intense to hues with exceptional durability. These pigments, exemplified by Pigment Red 149 (PR 149), exhibit high color strength due to their strong absorption in the , enabling efficient tinting at low concentrations. PR 149, a bluish- variant, demonstrates thermal stability up to 300°C, making it suitable for high-temperature processing, and achieves a lightfastness rating of 8 on the , indicating superior resistance to fading under prolonged exposure. The insolubility of PDI-based pigments in common solvents and resins prevents migration and bleeding, ensuring color integrity in finished products, while their excellent weather resistance withstands outdoor conditions without significant degradation. These properties stem from the robust aromatic structure of , which confers chemical inertness and stability against acids, alkalis, and atmospheric pollutants. Historically, perylene compounds were first synthesized in the early 1910s and initially commercialized by BASF as vat dyes, with pigment applications emerging in the 1950s for industrial use. BASF played a key role in scaling production, developing variants like perylene reds as durable alternatives to earlier polycyclic colorants. PDI pigments find widespread application in automotive coatings for their vibrant, long-lasting finishes; in plastics such as PVC, PP, and engineering polymers for coloration without compromising mechanical properties; and in printing inks for high-definition results on various substrates. Their optical properties contribute to vivid, transparent shades that enhance aesthetic appeal in these demanding sectors. In recent years (2020–2025), efforts toward have led to eco-friendly PDI variants optimized for lower environmental impact, including formulations with minimized impurities to reduce potential content from byproducts, aligning with regulatory demands for greener colorants. These advancements maintain the core performance of traditional PDIs while supporting applications in low-VOC coatings and recyclable plastics.

Optoelectronics and Materials

Perylene (PDI) derivatives have emerged as versatile n-type semiconductors in devices due to their strong , high mobility, and tunable optoelectronic properties through . In organic light-emitting diodes (OLEDs), PDIs serve as efficient electron transporters and blue , enabling devices with external quantum efficiencies (EQE) exceeding 5%. For instance, PDI-based non-doped blue OLEDs have achieved EQE values up to approximately 4-5%, approaching traditional limits for fluorescent materials, with ongoing advancements in dopant optimization and interface engineering reported from 2023 onward. These highlight PDIs' role in overcoming efficiency ceilings in deep-blue OLEDs. In dye-sensitized solar cells (DSSCs), PDI dyes function as sensitizers and n-type acceptors, contributing to power conversion efficiencies around 10% in recent configurations. A 2024 review of perylene-based dyes in DSSCs emphasizes structural modifications, such as bay-substitution, that broaden absorption spectra and improve injection, yielding efficiencies up to 6.8% in optimized PDI-sensitized devices under AM 1.5 conditions. Recent structural modifications have achieved power conversion efficiencies up to 6.8% as of 2024, with potential for further improvement through bay-substitution and co-sensitization strategies. These n-type semiconductors facilitate efficient charge separation and transport in DSSCs, with PDI's planar π-conjugated core enabling strong anchoring to TiO₂ surfaces while minimizing recombination losses. PDI-based systems have also shown promise in , particularly for hydrogen evolution reactions (HER). Supramolecular PDI assemblies, often incorporating heteroatoms or functionalization, generate built-in electric fields that drive charge separation, achieving visible-light-driven H₂ production rates enhanced by Pt co-catalysts. Studies from 2023 demonstrate PDI-TiO₂ heterostructures with H₂ evolution rates exceeding those of benchmark catalysts, attributed to PDI's role in extending light absorption into the visible range and suppressing electron-hole recombination. Recent progress includes bay-annulated PDIs in self-assembled , which exhibit stability over multiple cycles for sustainable H₂ generation. The of PDIs into columnar liquid crystalline structures further enables their application in organic field-effect transistors (OFETs), where ordered π-π stacking yields electron mobilities around 0.1 cm²/V·s. These discotic liquid crystals form one-dimensional charge pathways, with mobilities reaching 0.1–0.2 cm²/V·s in both liquid crystalline and crystalline phases, as observed in thin-film OFETs fabricated via solution processing. Advances from 2020–2025 have focused on substituent tuning to enhance crystallinity and alignment, improving device performance in and sensors. PDI liquid crystals thus bridge molecular design with macroscopic charge transport, offering scalable routes to high-mobility n-type materials.

Biological and Environmental Aspects

Natural Occurrence and Biology

Perylene quinones occur naturally in certain plants and lichens. , a prominent perylene quinone derivative, is primarily found in species of the genus , such as (St. John's wort), where it accumulates in glandular structures on leaves and flowers. Its natural biosynthesis in these plants involves pathways, though the exact enzymatic mechanisms remain under investigation. In lichens, perylene quinones like isohypocrellin and related compounds have been identified in species such as Laurera sanguinaria and Graphis haematites, contributing to their pigmentation and potential ecological roles in UV protection. As an environmental , perylene is detected in airborne particulates from incomplete combustion processes, including vehicle exhaust, industrial emissions, and burning. In aquatic environments, it accumulates in anoxic sediments at concentrations up to several parts per million, primarily through diagenetic transformation of rather than direct deposition. This leads to in organisms, such as corals and associated symbiotic , where perylene integrates into lipid-rich tissues via trophic transfer in webs. In biological research, perylene and its derivatives serve as fluorescent probes for cellular imaging. Unsubstituted perylene acts as a marker due to its high affinity for hydrophobic environments, enabling visualization of dynamics and phase separations like lipid rafts. Perylene diimide (PDI) derivatives, with enhanced water solubility and photostability, are used for targeted imaging, including mitochondrial to monitor and bioenergetic processes. A 2022 study demonstrated PDI-based supramolecular assemblies in antibacterial , where light activation generates to disrupt bacterial membranes without promoting resistance. Perylene derivatives interact with biomolecules through intercalation into DNA double helices, inserting between base pairs to alter structure and inhibit replication. This binding mode, observed in water-soluble PDI analogs, supports their use in probing dynamics and as potential anticancer agents by inducing in tumor cells.

Toxicity and Environmental Impact

Perylene exhibits low in mammals, with limited experimental data available, indicating minimal risk from single high-dose exposures. It is classified by the International Agency for Research on Cancer (IARC) as Group 3, not classifiable as to its carcinogenicity to humans, based on inadequate evidence from animal studies where no skin tumors were observed in mice following topical application. However, perylene demonstrates mutagenic potential, as evidenced by positive results in the using Salmonella typhimurium strains in the presence of a metabolic . Human exposure to perylene primarily occurs through (PAH) mixtures in , ambient , or occupational handling of dyes and pigments, where it may cause mild irritation upon prolonged contact but lacks evidence of acute systemic effects at environmental levels. In the , perylene is highly persistent due to its low solubility and high (log Kow = 6.04), leading to prolonged residence times in and sediments exceeding 100 days under conditions typical of depositional environments. It bioaccumulates readily in aquatic food chains, with an estimated bioconcentration factor (BCF) of 6700 in and observed accumulation in tissues via transfer from to symbiotic . As a marker PAH, perylene is routinely monitored in sediments to assess inputs and natural diagenetic processes. Perylene is classified under EU REACH as hazardous to the aquatic environment (Aquatic Chronic 1), with requirements for registration and in mixtures exceeding 0.1% concentration; while not among the 18 specifically restricted PAHs in consumer products like tires or articles, its presence in PAH mixtures triggers limits such as 1 mg/kg in contexts. Recent 2020s studies highlight its aquatic toxicity, including LC50 values of 1.1–5 μg/L for and 0.39–7033 μg/L for over 96 hours, underscoring risks to ecosystems. Remediation efforts have advanced with perylene diimide (PDI)-based photocatalysts, which degrade perylene and related PAHs under visible light, achieving high efficiency in as demonstrated in 2025 research.

References

  1. [1]
    Perylene | C20H12 | CID 9142 - PubChem - NIH
    Perylene is an ortho- and peri-fused polycyclic arene comprising of five benzene rings that is anthracene in which the d,e and k,l sides are fused to benzene ...
  2. [2]
    Perylene = 99 198-55-0
    ### Summary of Perylene Properties and Information
  3. [3]
    https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10094654/
  4. [4]
    https://webbook.nist.gov/cgi/cbook.cgi?ID=C198-55-0
  5. [5]
    Synthesis, photophysical and electronic properties of tetra-donor
    Jun 24, 2019 · The perylene core has 12 positions and can be considered as two naphthalene moieties conjoined at the 1 and 8 positions (Fig. 1).Missing: linked | Show results with:linked
  6. [6]
    The crystal and molecular structure of perylene - Journals
    Crystals of perylene, C 20 H 12 , are monoclinic with four molecules in a unit cell of dimensions a = 11.27 7 , b = 10.82 6 , c = 10.26 3 Å, B =Missing: central | Show results with:central
  7. [7]
    Perylene | 198-55-0 - ChemicalBook
    Jan 27, 2025 · Perylene Properties: Melting point 276-279 °C (lit.) Boiling point 400 °C Density 1.35 vapor pressure <0.001 hPa (20 °C) refractive index 1.6292 (estimate)Missing: physical | Show results with:physical
  8. [8]
    Perylene - the NIST WebBook
    Electron affinity determinations ; 0.9730 ± 0.0050, LPES, Scheidt and Weinkauf, 1997 ; 0.993 ± 0.043, IMRE, Crocker, Wang, et al., 1993 ; 0.35 ± 0.10, CIDC, Chen ...
  9. [9]
    Perylene - an overview | ScienceDirect Topics
    Perylene 1 is a polycyclic aromatic hydrocarbon; the atom numeration in perylene is given according to the IUPAC nomenclature. It was first synthesized in 1910 ...
  10. [10]
    Purification of perylene tetracarboxylic acid imide compounds
    A method of purifying perylene tetra carboxylic acid imide compounds prepared by caustic alkali fusion methods and containing among the impurities perylene ...Missing: purity | Show results with:purity
  11. [11]
    Perylene (purified by sublimation) - TCI Chemicals
    The purification by column-chromatography and repreciptitation affords the desired products. ... Purity / Analysis Method: >98.0%(GC). View Full Details. Product ...
  12. [12]
    Perylene Market Research Report 2033
    According to our latest research, the Global Perylene Market size was valued at $325 million in 2024 and is projected to reach $612 million by 2033, expanding ...
  13. [13]
    Sun Chemical Expands Perylene Pigment Capacity in Ludwigshafen
    Sun Chemical has expanded perylene pigment production capacity at its Ludwigshafen, Germany site, adding up to 200 metric tons of finished goods and ...
  14. [14]
    Perylene Production Cost Analysis Reports 2025
    Procurement Resource provides in-depth cost analysis of Perylene production, including manufacturing process, capital investment, operating costs, ...
  15. [15]
    Perylene - an overview | ScienceDirect Topics
    Perylene is defined as an organic compound that serves as an industrial dye, notable for its stability and excellent optical and electronic properties, ...
  16. [16]
    Soft and Sustainable Synthesis of Perylene Diimides through ...
    Apr 22, 2025 · An unprecedented strategy for the efficient and direct synthesis of perylene-3,4,9,10-tetracarboxylic diimides (PDIs) through a well-defined and controlled ...Missing: laboratory | Show results with:laboratory
  17. [17]
    News - Sustainability and Innovation: The New Age of Perylene ...
    Sustainability and innovation have taken center stage in today's industrial landscape, driving pivotal transformations in manufacturing processes across.
  18. [18]
    An Exemplary Case of Alkali Metal Ca - ACS Publications
    The hydrocarbon perylene (C20H12) has been crystallized, and several of its radical anions and dianion salts have been prepared by reduction with various ...
  19. [19]
    [PDF] Article - Allen J. Bard
    reduction potential of PI is less negative than that of perylene. (-1.68 V vs SCE).18. The measured redox potentials for the series of compounds with ...Missing: C20H12 E1/
  20. [20]
    [PDF] Analytical Applications of Electron Spin Resonance. - DTIC
    Initially, the spectrum of the perylene radical anion appears and. ~. •. ~~~. ' reaches a steady state. Gradually as the perylene is reduced to the dianion,. I.
  21. [21]
    Stability and Reactivity of Aromatic Radical Anions in Solution with ...
    Comparison with the X-ray crystallography data of the [C10H 8 •–][Na+(diglyme)2] crystals grown from diglyme solutions where Np had been reduced by sodium, (84) ...
  22. [22]
    Preparation and Purification of Some Oxidation Products of Perylene
    Analytically pure dione 2 has been obtained by two methods of purification: (a) column chromatography on silica gel, and (b) adsorption chromatography on ...Missing: industrial | Show results with:industrial
  23. [23]
    A simple protocol for the synthesis of perylene bisimides from ...
    Apr 8, 2024 · Zinc acetate and zinc chloride catalysts were also used to increase the reactivity of aromatic amines. The non ...
  24. [24]
    Green synthesis of perylene diimide-based nanodots for carbon ...
    PDIs are commonly synthesized by condensing perylene-3,4,9,10-tetracarboxylic dianhydride (PTCDA) or its analogues with anilines and aliphatic primary amines in ...Green Synthesis Of Perylene... · Abstract · Introduction<|separator|>
  25. [25]
    Review of Pyrene- and Perylene-Based Photocatalysts: Synthesis ...
    Sep 16, 2025 · This review presents recent advancements in pyrene- and perylene-based photocatalysts, emphasizing synthesis, functionalization, and the ...Introduction · Synthesis and Characteristics... · Development of Pyrene- and...
  26. [26]
    Facile synthesis of terrylene and its isomer benzoindenoperylene
    Oxidative cyclodehydrogenation of 3-(1-naphthyl)perylene selectively afforded terrylene or its isomer, benzo[4,5]indeno[1,2,3-cd]perylene. The yield of ...
  27. [27]
    [PDF] Bis-N-Annulated Quaterrylene: An Approach to Processable ...
    The reactivity of the precursor, the amount of DDQ/. Sc(OTf)3, as well as the reaction temperatures are presumed to be key factors to oxidative coupling and ...
  28. [28]
    New Highly Fluorescent Water Soluble Imidazolium-Perylenediimides
    Jul 5, 2023 · Abstract. The synthesis and characterization of two new water soluble 2,6-bis(imidazolylmethyl)-4-methylphenoxy-containing perylenediimides, ...Missing: 2020-2025 | Show results with:2020-2025
  29. [29]
    Perylene - PhotochemCAD
    Perylene has an absorption wavelength of 435.75 nm with an absorption coefficient of 38500, and a fluorescence quantum yield of 0.94.
  30. [30]
    Absorption and emission spectroscopy of perylene - AIP Publishing
    The electronic absorption and emission spectra of perylene ( C 20 H 12 ) isolated in rare gas (Ne, Ar) and N 2 matrices are presented.
  31. [31]
    Solvatochromism in perylene diimides; experiment and theory
    We report an experimental and computational investigation into the solvatochromism of a perylene diimide derivative. The alkyl swallowtail substituents ...
  32. [32]
    Electronic Absorption Spectra of Neutral Perylene (C 20 H 12 ...
    However, the TDDFT transition moment of perylene is 2.1847ea0, which is far from the ideal (weakly coupled) value. By contrast, for two weakly interacting ...Introduction · II. Methods · III. Results and Discussion · IV. ConclusionsMissing: TD- | Show results with:TD-
  33. [33]
    Low-lying excited states in crystalline perylene - PNAS
    Dec 26, 2017 · The HOMO–LUMO transition is assigned at 2.98 eV. Linear combinations of two vibrons with energies of 42 and 164 meV lead to a series of vibronic ...
  34. [34]
    Crystalline assembly of perylene in metal–organic framework thin film
    We predict the structural assembly of the perylene molecules in the MOF via robust periodic density functional theory calculations and discuss the impact of ...
  35. [35]
    Perylene nanostructured films optimization for organic electronics
    Jul 31, 2023 · The perylene film showed linear growth and the formations of H and J aggregates. •. The film has a preferential head-on orientation with a ...
  36. [36]
    Spectrum [Perylene] - AAT Bioquest
    Perylene is a fluorescent compound with an excitation peak at 436 nm and an emission peak at 467 nm. It can be excited using a 445 nm laser paired with a ...
  37. [37]
    Perylene - OMLC
    Perylene's absorption has a molar extinction of 38,500 cm⁻¹/M at 435.8nm. Its fluorescence emission spectrum has a quantum yield of 0.94.Missing: maxima ε
  38. [38]
    https://pubs.aip.org/aip/jcp/article-pdf/doi/10.1063/5.0069398/15809628/191102_1_online.pdf
  39. [39]
    Detection of long S2 lifetime of perylene - AIP Publishing
    9 The detected fluorescence lifetime of perylene in hexane is. 4.1 ns,6(d) in agreement with the literature data.10. Femtosecond TA spectra and kinetics of ...
  40. [40]
    Improving the Quantum Yields of Perylene Diimide Aggregates by ...
    Jun 19, 2017 · The monomer emission lifetime was 4.8 ns whereas a lifetime as high as 21.2 ns was measured for the B13 aggregate fluorescence. A shorter ...
  41. [41]
    Quenching of Fluorescence by Oxygen. A Probe for Structural ... - NIH
    Jan 14, 2020 · Oxygen quenching of perylene in dodecane is an example (Figure 7). Such positive deviations may be described in terms of a static quenching ...
  42. [42]
    Unusually efficient quenching of the fluoroscence of an energy ...
    The fluorescence of pyrene is strongly quenched by oxygen, but that of perylene is not. The two-fluorophore system, in contrast, is very strongly quenched, with ...
  43. [43]
    Fluorescence properties of β-perylene crystals prepared by a ...
    The fluorescence lifetime (τF) was determined to be 12.3 ns and the annihilation rate constant (γss) of singlet exciton was estimated to be 3 × 10−10 cm3 s−1 ...
  44. [44]
    Decay mechanisms of a blue organic light emitting diode
    Aug 9, 2004 · A blue organic light-emitting diode employing perylene as light emitting dopant and 9,10-bis(3'5'-diaryl)phenyl anthracene (DPA) as host has ...
  45. [45]
    Single-molecule detection of a terrylenediimide-based near-infrared ...
    Sep 24, 2024 · We report a novel NIR absorbing (λ Abs max = 734 nm) and emitting (λ Fl max = 814 nm) terrylenediimide (TDI) based donor–acceptor chromophore (TDI-TPA<|control11|><|separator|>
  46. [46]
    Perylene‐Embedded Helical Nanographenes with Emission up to ...
    Oct 4, 2024 · This long wavelength absorption suggests a potential emission peak exceeding 1000 nm. ... (a) UV/Vis absorption spectra and (b) fluorescence ...<|control11|><|separator|>
  47. [47]
    Perylene Pigments - ResearchGate
    The perylene pigments were first synthesized in the 1910s and initially used exclusively as vat dyes and since the 1950s they were used as pigment (Greene, 2009 ...
  48. [48]
    DuraPlast@3549 Pigment Red 149 | Fineland Chem
    A high-performance, slightly bluish-red perylene pigment designed for use in engineering polymers and fibers, offering outstanding heat stability up to 300 °C, ...
  49. [49]
    1149 Perylene Red, PR.149 - DCL Corporation
    1149 is recommended for solvent based industrial, powder coatings, solvent based printing inks, and plastic applications including but not limited to: flexible ...
  50. [50]
    Pigment Red 149-Corimax Red 3580 - Zeya Chemicals
    Recommended for automotive paints, industrial paints, powder coatings, printing pastes, PVC, rubber, PS, PP, PE, PU, water based inks, solvent inks, UV inks.
  51. [51]
    Perylene-S ^ ÄlO-tetracarboxylic acid diimide pigment, process for ...
    Application filed by BASF SE. 1975-10-16. Priority to DE2546266A. 1977-04-21 ... The new coloristic properties of the new pigment form are also derived ...
  52. [52]
    Organic Pigment Red 149 | P.R.149 Perylene Red Similar to BASF ...
    Pigment red 149 is also particularly suitable for automotive coatings, industrial coatings and powder coatings that have strict weather resistance requirements.
  53. [53]
    Modification of perylene red pigments with graphene oxide
    The color and dispersion stability properties of modified Pigment Red 179 and 149 are obviously improved by the addition of graphene oxide and ball milling. The ...
  54. [54]
    Overcoming the 5% EQE ceiling in deep-blue fluorescent OLEDs ...
    Notably, the doped device employing PICz-BP achieved excellent performance, delivering a maximum EQE of 6.1% with deep-blue emission (CIEy ≈ 0.06). Remarkably, ...
  55. [55]
    Highly efficient non-doped blue OLED based on perylene
    Aug 6, 2025 · An efficient non-doped blue organic light-emitting diode with several-nanometer-thick easy-to-aggregate fluorescent material perylene is ...
  56. [56]
    Effect of Extending the Conjugation of Dye Molecules on the ...
    The YL4-based DSSC exhibits the best solar-to-electricity conversion efficiency of up to 9.79% and 10.87%, resp., without and with the CDCA co-adsorbent. These ...
  57. [57]
    Perylene‐Based Dyes in Dye‐Sensitized Solar Cells: Structural ...
    Oct 17, 2024 · This critical analysis compares and discusses the state of the art of the rylene-based dyes, starting from the pioneering studies on the perylene bisimides to ...
  58. [58]
    Recent advancements in perylene diimide as an electron acceptor ...
    One of the famous non-fullerene acceptors, known as perylene diimide (PDI), will be reviewed in this manuscript.Missing: efficiency | Show results with:efficiency
  59. [59]
    High photocatalytic hydrogen evolution via strong built-in electric ...
    Three heteroatom bay-annulated perylene diimide supramolecule photocatalysts (N-APDI, S-APDI and Se-APDI) were developed for photocatalytic H 2 evolution.Missing: H2 | Show results with:H2
  60. [60]
    functionalized perylene diimide integrated Ti3+ self-doped TiO2 ...
    Hydrazine -functionalized perylene diimide integrated Ti3+ self-doped TiO2 heterostructure for visible light-driven photocatalytic H2 evolution. October 2023 ...
  61. [61]
    Recent Progress and Challenges in Perylene Small Molecules ...
    Nov 28, 2023 · In this review, the developments of PDI-based photocatalysts for H 2 evolution are outlined under four different categories.
  62. [62]
    Electron Transport in Soft-Crystalline Thin Films of Perylene Diimide ...
    Dec 12, 2024 · We have examined the structural and electron transport properties of a swallow-tailed N,N'-bis(1-heptyloctyl)-perylene-3,4:9,10-bis(dicarboximide) (PDI-C8,7) ...
  63. [63]
    Liquid Crystalline Perylene diimides : Architecture and Charge ...
    ... and ... A value in excess of 0.1 cm2 V-1 s-1 is found in the liquid crystalline phase, and a value in excess of 0.2 cm2 V-1 s-1 is found for the crystalline phase ...Missing: OFET | Show results with:OFET
  64. [64]
    Synthesis and Optoelectronic Properties of Perylene Diimide-Based ...
    Feb 9, 2025 · This reaction is carried out through a condensation process in high-boiling-point solvents, such as imidazole, porphyrins, or N-methyl-2- ...
  65. [65]
    Hypericin: chemical synthesis and biosynthesis - PubMed
    Hypericin is one of the most important phenanthoperylene quinones extracted mainly from plants of the genus Hypericum belonging to the sections Euhypericum ...
  66. [66]
    [PDF] Draculone, a New Anthraquinone Pigment from the Tropical Lichen ...
    crocin, isohypocrellin and related perylenequi- nones occur in Laurera sanguinaria and xanthorin in Laurera purpurina (Mathey, 1987; Mathey et al.,. 1987 ...
  67. [67]
    Significance of Perylene for Source Allocation of Terrigenous ...
    Jun 19, 2019 · Here we investigate whether perylene serves as a source-specific molecular marker of fungal activity in forest soils.<|separator|>
  68. [68]
    Biomonitoring of perylene in symbiotic reef and non-reef building ...
    Aug 24, 2020 · Due to the insolubility of PAHs, they could be transferred through a food chain to zooxanthellae and eventually deposited in the coral bodies.
  69. [69]
    Visualization of Membrane Rafts Using a Perylene Monoimide ...
    Normalized absorption and emission spectra (the excitation wavelength was 488 nm), quantum yields, and decay times of the PMI-COOH derivative in different ...
  70. [70]
    Recent Advances in Applications of Fluorescent Perylenediimide ...
    This review covers the state of the art in the synthesis, photophysical characterizations and recently reported applications demonstrating the versatility of ...3. Pdi And Pmi Structures... · 5.1. Synthesis And... · 5.2. Synthesis And...Missing: antibacterial | Show results with:antibacterial
  71. [71]
    An Effective Supramolecular Approach to Boost the Photodynamic ...
    Mar 9, 2022 · Perylene diimide (PDI) derivatives with outstanding photo-physicochemical properties hold significant promise for application in solar ...
  72. [72]
    A unique perylene-based DNA intercalator: localization in cell nuclei ...
    Oct 29, 2014 · To date, perylene derivatives have not been explored as DNA intercalator to inhibit cancer cells by intercalating into the base pairs of DNA ...