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Coronene

Coronene is a polycyclic aromatic hydrocarbon (PAH) with the molecular formula C24H12, consisting of seven peri-fused benzene rings arranged in a symmetric, circular honeycomb pattern that mimics a small fragment of graphene. It exhibits D6h point group symmetry and possesses 24 π-electrons, making it a highly conjugated, planar molecule often referred to as "superbenzene" or circulene. Physically, coronene appears as a yellow to greenish crystalline powder with a molecular weight of 300.35 g/, a of 428 °C, and a of 525 °C at reduced . It has a of 1.39 g/cm³ and shows limited solubility in (0.1 µg/L at 25 °C) but dissolves moderately in organic solvents such as , , , and . Under light, coronene fluoresces blue, with absorption maxima around 310–343 nm and emission at approximately 447 nm. Chemically stable and combustible, it is incompatible with strong oxidizing agents. The Agency for Research on Cancer (IARC) classifies it as Group 3: not classifiable as to its carcinogenicity to humans. Coronene occurs naturally in various environmental contexts, including as a component of nascent particles formed during processes, where it serves as a model for PAH growth in atmospheric and exhaust. It has been identified in meteorites and is believed to contribute to the complex observed in astronomical environments, such as infrared emission bands from polycyclic aromatic hydrocarbons. In 2025, the related cyanocoronene was directly detected in the . Additionally, trace amounts have been identified in , prompting toxicity assessments due to its PAH nature. Synthetically, coronene can be prepared through methods like vacuum after from or , or via gas-phase reactions mimicking conditions for studies. More advanced involve cyclization of polyaromatic precursors or surface-mediated growth on metal substrates, enabling the production of high-purity forms for research. In applications, coronene is valued in for its role in , where its high charge carrier mobility and transparency support electron transport layers in organic (OPVs) at thicknesses up to 25 . It enables RGB from single crystals—blue, green, and red. It exhibits phosphorescent properties when doped into polymer matrices. Furthermore, coronene serves as a precursor in synthesis, such as through evaporation onto copper surfaces at high temperatures, and as a model compound for studying formation, precursors, and the electronic structure of extended π-systems.

Structure and properties

Molecular structure

Coronene is a with the molecular formula C_{24}H_{12}. It consists of seven peri-fused rings arranged in a highly symmetric, hexagonal pattern, with a central ring surrounded by six outer rings, resulting in a flat, disk-shaped . In its isolated or gas-phase form, coronene exhibits D_{6h} symmetry, characterized by a planar where all carbon atoms lie in the same and the peripheral hydrogen atoms are equivalently positioned. This high arises from the uniform fusion of the aromatic rings, contributing to its stability and electronic delocalization across the \pi-system involving 24 \pi-electrons. X-ray crystallographic studies of the solid state reveal that the remains nearly , with maximum carbon atom displacements from the mean of only 0.029 , though intermolecular forces induce slight distortions that lower the effective to C_3. lengths show alternation typical of aromatic systems: outer peripheral bonds average 1.346 and 1.415 , spoke-like bonds connecting to the center are 1.433 , and central bonds are 1.425 . These features underscore coronene's role as a model compound for understanding extended aromatic systems in .

Physical properties

Coronene appears as a to yellow-gold crystalline powder or fibrous solid. It has a of 438 °C (range 437–440 °C) and a of 525 °C at reduced . The is 1.371 g/cm³ at 25 °C. Coronene exhibits very low in , approximately 0.1 μg/L at 25 °C, reflecting its nonpolar aromatic nature. In contrast, it shows moderate solubility in nonpolar organic solvents, such as aromatic hydrocarbons like and , with values ranging from 0.5 to 15 mg/mL depending on the solvent and conditions. Solubilities in aliphatic solvents like n-heptane are significantly lower, around 0.00048 mol/dm³ at 20 °C. In the solid state, coronene crystallizes in a monoclinic with P2₁/a and parameters a = 16.119 , b = 4.702 , c = 10.102 , β = 110.9°, and Z = 2. This structure features herringbone packing of the planar molecules, akin to fragments, which contributes to its stability and π-π interactions. Under up to 30.5 GPa, coronene undergoes phase transformations, including a transition to a denser polymorph around 3 GPa, accompanied by changes in vibrational modes.

Electronic and spectroscopic properties

Coronene exhibits a closed-shell singlet ground state with a highly delocalized π-electron system across its seven fused benzene rings, resulting in a relatively large HOMO-LUMO energy gap. Density functional theory (DFT) calculations using time-dependent methods such as TD-wB97XD with the cc-pVDZ basis set predict a HOMO-LUMO gap of approximately 3.94 eV for the neutral molecule, reflecting its stability and resistance to oxidation or reduction under ambient conditions. Experimentally, the vertical ionization potential is measured at 7.29 ± 0.03 eV, while the adiabatic electron affinity is 0.47 ± 0.09 eV, yielding a fundamental gap of about 6.82 eV; these values underscore coronene's role as a wide-bandgap organic semiconductor with potential in optoelectronic devices. Thermally-assisted occupation DFT (TAO-DFT) further refines these, estimating a vertical ionization potential of 6.05 eV, vertical electron affinity of 0.95 eV, and fundamental gap of 5.10 eV, highlighting the method's utility for capturing electron correlation effects in extended π-systems. The ultraviolet-visible (UV-Vis) absorption spectrum of coronene in solution features distinct bands attributed to π-π* , with a maximum at 378 corresponding to the lowest-energy allowed (¹B_{2u} ← ¹A_{1g} in D_{6h} symmetry), though stronger occur at shorter wavelengths around 310–343 . Additional features occur at shorter wavelengths, such as around 346 , reflecting higher-energy excitations involving multiple benzene-like subunits; these spectra are solvent-dependent, with polar media inducing slight bathochromic shifts due to stabilization of the excited states. In the solid state, polymorphism influences the onset, as seen in the β-phase where it extends to 780 , indicating intermolecular interactions that narrow the effective bandgap. Coronene displays multiple emissions originating from its S₁ (¹B_{2u}), S₂ (¹B_{1u}), and S₃ (¹E_{1u}) excited states, with the S₁ dominating in and vapor phases, peaking broadly between 357 nm and 417 nm (24,000–28,000 cm⁻¹). The S₁ emission decreases with higher excitation energy, while S₂ and S₃ emissions, though weaker, increase correspondingly, revealing efficient and pathways; the S₁ lifetime is approximately 4.9 , quenched significantly by oxygen. These properties arise from the molecule's high , which forbids certain transitions and leads to sharp, structured spectra at low temperatures, making coronene a for studying PAH photophysics.

Occurrence and sources

Natural occurrence

Coronene, a high-molecular-weight polycyclic aromatic hydrocarbon (PAH), occurs naturally in various geological environments, primarily as a component of fossil fuels and sedimentary deposits formed through diagenetic and catagenetic processes. It is present in crude oil, where it constitutes a minor but detectable fraction among heavier PAHs, typically at trace levels alongside compounds like pyrene and fluoranthene. In coal deposits, such as those from the Permian period in India, coronene has been identified in association with other PAHs, reflecting geological episodes involving organic matter maturation under heat and pressure. These terrestrial occurrences arise from the thermal alteration of ancient organic material, including plant debris and marine sediments, over millions of years. Coronene is also found in hydrothermal petroleum systems on the seafloor, where it forms part of complex mixtures generated by high-temperature fluid interactions with organic-rich sediments. For instance, it has been detected in samples from the Escanaba Trough and Guaymas Basin, highlighting its role in subsurface geochemical cycles driven by volcanic activity. Such environments demonstrate coronene's stability under extreme conditions, contributing to its preservation in deep-sea sediments and potentially influencing global carbon cycling. Extraterrestrially, coronene is present in carbonaceous chondrite meteorites, including the Murchison and Allende meteorites, where it appears alongside its methylated derivatives as part of high-molecular-weight PAH assemblages. These findings support the hypothesis that coronene and similar PAHs originate in the interstellar medium (ISM) through processes like high-temperature synthesis in stellar envelopes or circumstellar regions, subsequently incorporated into meteoritic material. While direct gas-phase detection of neutral coronene in the ISM remains elusive, its presence in meteorites reinforces models attributing unidentified infrared emission features to PAH vibrations throughout the galaxy. Recent observations of related species, such as cyanocoronene, further indicate that coronene-like structures are viable in interstellar clouds.

Anthropogenic production

Coronene, a high-molecular-weight (PAH), is primarily produced anthropogenically through incomplete processes and certain operations. These sources contribute significantly to its presence in atmospheric aerosols, air, and environmental matrices, often serving as a tracer for PAH emissions due to its and formation under high-temperature conditions. In combustion-related activities, coronene forms during the and oxidation of organic fuels at temperatures exceeding 700°C, particularly in oxygen-deficient environments. Vehicle emissions, especially from engines, are a major source, with coronene detected in from exhaust, alongside other PAHs like benzo[ghi]perylene. Studies of atmospheres show elevated coronene levels correlating with traffic density. Residential burning, including wood, crop residues, and pellets, also releases coronene. Industrial , such as coal-fired power plants and waste , further contributes, though and residential sources dominate urban inventories. Beyond , coronene arises in processes, notably hydrocracking of heavy fractions, where it accumulates as a during the catalytic breakdown of asphaltenes and resins under high (up to 200 bar) and temperatures (350-450°C). In this process, coronene can dimerize to dicoronylene, complicating operations by fouling catalysts and reducing yields. production from and also yields coronene, comprising 0.5-2% of PAH content in tar distillates, derived from the of at 900-1100°C. These industrial streams release coronene into and air emissions.

Synthesis

Early synthesis methods

The first laboratory synthesis of coronene was achieved in 1932 by Roland Scholl and Kurt Meyer through a multi-step process involving the construction of a larger precursor, anti-diperi-dibenzocoronene, followed by its selective degradation. Their route began with a Friedel–Crafts acylation of m-xylene using phthalic anhydride to form a keto acid, which was esterified and reduced to yield an anthraquinone derivative; subsequent acetylation, cyclization, and further transformations built the dibenzocoronene framework, which was then cleaved under oxidative conditions to afford coronene as the core fragment. This pioneering method, though lengthy (over 10 steps) and low-yielding, confirmed coronene's structure and established it as a synthetically accessible polycyclic aromatic hydrocarbon. In 1940, Melvin S. Newman reported a more concise , reducing the sequence to six steps starting from 7-methyl-3,4-dihydro-2H-naphthalen-1-one (7-methyltetralone), with an overall yield of approximately 1.7%. Key transformations included selective functionalizations to build peripheral rings via cyclodehydrogenation and , leveraging the tetralone's pre-existing fused ring system to streamline assembly compared to the Scholl-Meyer approach. This method highlighted the potential for shorter routes using partially pre-fused precursors, influencing subsequent PAH syntheses despite the modest efficiency. An improved variant was developed in 1952 by Wilson Baker and colleagues, optimizing yields through refined cyclization conditions and purification in a route derived from earlier strategies, achieving better for preparative purposes. These early methods predominantly relied on classical transformations like Friedel–Crafts reactions, , and oxidative cyclodehydrogenations, often employing aluminum chloride or similar Lewis acids, and laid the groundwork for understanding coronene's reactivity in ring-building processes.

Contemporary synthesis and crystal engineering

Contemporary synthesis of coronene relies on refined multi-step organic transformations, often incorporating photocyclization and strategies to construct the symmetric circulene core from smaller aromatic precursors. A widely adopted route begins with the preparation of (E)-1,2-bis(3,6-dimethoxynaphthalen-2-yl)ethene, which undergoes oxidative photocyclization to form tetramethoxybenzo[ghi]perylene. This intermediate then participates in a Diels-Alder with chloranil as the dienophile, adding the central ring, followed by and to yield the coronene framework; this method has been employed in the synthesis of substituted coronenes with moderate overall efficiency. Advancements in gas-phase radical chemistry have illuminated non-traditional pathways, particularly relevant to astrophysical formation. In a 2023 study, coronene was synthesized in the gas phase through stepwise, directed ring annulation mediated by aryl radicals, initiating from naphthalene (C10H8) and progressing via resonant-stabilized intermediates such as phenanthrene (C14H10), benzopyrene (C20H12), and benzo[ghi]perylene (C22H12), with the final C2H addition closing the seventh ring; quantum chemical calculations confirmed the low-barrier nature of these H-assisted annulations under high-temperature conditions. Surface-mediated approaches enable precise bottom-up assembly for applications. For instance, deposition of a tribrominated sumanene derivative on Au(111) at 150 °C induces intramolecular rearrangement to individual coronene units within an organometallic lattice, while annealing at 225 °C promotes covalent coupling via cyclobutadiene bridges, forming porous networks with a semiconducting of ~0.8 eV, as characterized by scanning tunneling . Functionalized variants, such as persulfurated coronene, have been achieved through selective formation around the periphery, yielding a sulfur-rich "sulflower" structure with potential as a lithium-sulfur , retaining 90% capacity (520 mAh g⁻¹) after 120 cycles. Crystal engineering of coronene exploits its polymorphism and phase behavior to tailor solid-state properties for and . The conventional γ-herringbone polymorph (monoclinic, P2₁/a) dominates under ambient conditions, but application of a 1 T during slow cooling of a supersaturated solution (0.04 K/min from 328 K) suppresses γ-nucleation and selectively yields the metastable β-herringbone form (monoclinic, P2₁/c), featuring a herringbone angle of 49.71° and interlayer spacing of 3.48 ; this polymorph displays extended panchromatic absorption up to 847 nm and reduced (92 GPa versus 227 GPa for γ), attributed to weaker CH⋯π interactions. Phase transitions between these polymorphs enable dynamic functionalities in nanostructured forms. Single-crystal nanofibers (300–700 nm wide, 50–200 nm thick) undergo a martensitic γ-to-β upon cooling to ~150 K, inducing ultrafast anisotropic contraction (23% along the b-axis) that propels jumping motions with velocities up to 20 m/s and distances of several centimeters, alongside and wriggling; heating to ~220 K reverses the process with slower dynamics (1–5 m/s), highlighting coronene's potential in photo- or thermo-actuated nanodevices. Halogenation strategies further diversify crystalline motifs. Solid-state treatment of coronene with CoF₃ at 250–300 °C produces edge-perfluorinated coronene as a of stereoisomers (9% ), which serves as a precursor for dodecakis(phenylthio)coronene; the latter assembles into columns via short CH–π (2.7 ) and CH–S (2.9 ) contacts in a monoclinic ( C2/c), with the core exhibiting saddle-shaped distortion for enhanced π-stacking coherence.

Applications

In materials science and nanotechnology

Coronene's planar, disc-like structure and extended π-conjugation make it a versatile building block in , particularly for self-assembling into ordered nanostructures with potential in and . Its ability to form columnar stacks and hexagonal lattices facilitates charge transport and light emission, enabling applications in thin-film devices. Derivatives of coronene have been engineered to enhance solubility and processability, allowing deposition via solution-based methods for scalable . In , coronene-based materials exhibit high charge-carrier mobilities, making them suitable for organic field-effect transistors (OFETs) and organic light-emitting diodes (OLEDs). For instance, room-temperature discotic liquid-crystalline coronene diimides demonstrate electron mobilities up to 6.7 cm² V⁻¹ s⁻¹ in air, attributed to their columnar stacking that provides one-dimensional conduction pathways. Similarly, heterocoronene derivatives form columnar phases with hole mobilities exceeding 1 cm² V⁻¹ s⁻¹, supporting ambipolar transport in . Coronene has also been incorporated into two-dimensional metal-organic frameworks (MOFs), yielding semiconducting films with tunable bandgaps for photovoltaic and sensor applications. Nanotechnology leverages coronene as a molecular precursor for -like structures, including nanoribbons formed by within nanotubes, which insulate the ribbons for quantum device integration. As a finite model for nanoflakes, coronene simulates ultrafast excitonic dynamics and , aiding the design of carbon-based with predicted lifetimes under 100 fs for photoexcited states. Self-assembled coronene nanofibers and microwires serve as chemiresistive sensors for electron-deficient aromatics, showing detection limits in the ppm range due to π-π interactions. In hybrid systems, coronene/MoS₂ van der Waals heterostructures enhance local , promising for nano-optoelectronics. Additionally, contorted derivatives function as anodes in lithium-ion batteries, delivering capacities over 300 mAh g⁻¹ with improved cycling stability from their crystalline packing.

In research and analytical techniques

Coronene serves as a valuable standard in due to its high of approximately 0.23 in and sharp emission bands, enabling accurate calibration of measurements and photophysical studies of polycyclic aromatic hydrocarbons (PAHs). In (NMR) spectroscopy, it is employed to evaluate through isotropic shielding contour plots and nucleus-independent (NICS) indices, providing insights into π-electron delocalization in extended aromatic systems. In chromatographic techniques, coronene acts as a reference compound for the analysis of PAHs in environmental samples, particularly in (HPLC) and gas chromatography-mass spectrometry (GC-MS). For instance, it is included in standard methods like EPA TO-13A for quantifying PAHs on , where its long retention time in toluene-eluted Buckyprep columns—due to strong π–π interactions—facilitates separation of high-molecular-weight PAHs. In capillary extraction and in-tube extraction methods, coronene's extreme hydrophobicity highlights limitations in aqueous , aiding method validation for hydrophobic analytes. For environmental source apportionment, coronene functions as a tracer for anthropogenic PAH emissions, especially from vehicle exhaust. The benzo(a)pyrene/coronene ratio, often exceeding 1 for gasoline emissions but lower for diesel, distinguishes combustion sources in soil, sediment, and air samples, as demonstrated in studies of urban pollution. In surface science research, coronene is a model molecule for scanning tunneling microscopy (STM) investigations of PAH adsorption and self-assembly on substrates like Au(111) and highly oriented pyrolytic graphite (HOPG). Electrochemical STM reveals potential-dependent formation of ordered adlayers with iodine co-adsorption, while ultra-high vacuum STM visualizes molecular islands and diffusion, informing graphene-like nanostructure design. Mass spectrometry applications leverage coronene for studying PAH ionization and fragmentation. Near-edge X-ray absorption mass spectrometry (NEXAFS-MS) examines of coronene cations, yielding insights into carbon K-edge pathways relevant to atmospheric and astrophysical . Laser-induced fragmentation spectra, dominated by C11+ and C7H+ peaks, further elucidate reaction mechanisms in environments.