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Fluorenone

Fluorenone, also known as 9-fluorenone, is an aromatic with the molecular formula C13H8O and number 486-25-9. It features a planar structure composed of two rings fused to a central five-membered ring bearing a at the 9-position, making it the simplest member of the fluoren-9-ones class. This yellow crystalline solid has a of 81–85 °C, a of 342 °C at 760 mmHg, and low in (approximately 0.0001 g/100 mL at 25 °C), though it dissolves readily in organic solvents such as , , and . Fluorenone is primarily synthesized through the oxidation of fluorene, often using or other oxidizing agents like air in the presence of catalysts, yielding the compound in high purity after or . More modern methods include palladium-catalyzed of o-halobiaryls or aerobic oxidation of substituted fluorenes, enabling the preparation of diverse derivatives. As a versatile intermediate, fluorenone finds extensive applications in the of fine chemicals, including bisphenol fluorene and 2,4,7-trinitrofluorenone, as well as in the production of resins such as fluorenylbenzoxazine, , and resins. It serves as a precursor for pharmaceuticals, pesticides, dyes, and in , notably in organic light-emitting diodes (OLEDs), solar cells, and fluorescent probes due to its photophysical properties. Additionally, fluorenone derivatives exhibit potential in biological imaging and chemosensing, highlighting its role in both industrial and research contexts.

Structure and properties

Molecular structure and nomenclature

Fluorenone, with the 9H-fluoren-9-one, is also known by the synonyms 9-fluorenone, 9-oxofluorene, and diphenylene ketone. Its molecular formula is C₁₃H₈O. The compound features a aromatic structure composed of two rings fused to a central five-membered ring, where a is positioned at the 9-carbon. This arrangement forms a core bridged by the between the rings, enabling extensive π-conjugation across the molecule. The adopts a planar due to the delocalized . crystallographic analysis reveals a C=O of approximately 1.21 , consistent with a typical carbonyl, while the aromatic C-C bonds measure around 1.39–1.41 , reflecting the aromatic delocalization.

Physical properties

Fluorenone is a bright crystalline solid at . Its is 180.206 g/mol. The has a of 1.130 g/cm³ measured at 99 °C. Fluorenone melts at 84.0 °C and boils at 341.5 °C under standard pressure of 760 mmHg. These thermodynamic properties reflect its stability as a solid under ambient conditions and its relatively high due to strong intermolecular forces in the pure form. Fluorenone exhibits low in , with values below 0.1 g/L at 25 °C, indicating poor aqueous . In contrast, it is soluble in polar organic solvents such as , acetone, and , and shows high in nonpolar solvents like and , exceeding 100 g/L. This solvent-dependent behavior underscores its lipophilic nature, quantified by an () of approximately 3.6. The of fluorenone is 163 °C, and its is 608 °C, signifying moderate flammability risks under elevated temperatures. Vapor pressure is low, estimated at 5.7 × 10^{-5} mmHg at 25 °C, which limits its volatility in environmental contexts. The bright yellow appearance stems from its extended conjugated π-system.

Spectroscopic properties

Fluorenone exhibits characteristic ultraviolet-visible (UV-Vis) absorption bands attributed to π-π* transitions in the aromatic around 250 and a weaker n-π* transition involving the at approximately 380 in nonpolar solvents such as . These transitions arise from the extended conjugation in the fluorenone framework, enabling structural identification through . In solution, fluorenone displays bright yellow-green with an maximum near 500-520 upon at the longer-wavelength band, a property linked to its conjugated π-. Infrared (IR) reveals a prominent carbonyl at 1715 cm⁻¹, indicative of the conjugated functionality, which appears as a sharp, intense band due to the reduced C=O compared to aliphatic s. Aromatic C-H modes are observed in the 3000-3100 cm⁻¹ region, confirming the presence of the fused aromatic rings. (NMR) spectra provide detailed insights. The ¹H NMR spectrum shows eight aromatic protons appearing as multiplets in the range of 7.2-7.8 , reflecting the symmetric C_{2v} with two sets of four protons each. In the ¹³C NMR spectrum, the carbonyl carbon resonates at approximately 194 , while the aromatic carbons span 120-140 , with carbons at higher shifts reflecting their positions relative to the electron-withdrawing carbonyl. Mass spectrometry of fluorenone displays a molecular ion peak at m/z 180 corresponding to [C_{13}H_8O]⁺, with a prominent base peak at m/z 152 from the loss of CO, highlighting the stability of the fragment ion and the lability of the carbonyl group under electron impact conditions. Electron paramagnetic resonance (EPR) spectroscopy has been applied to study the radical anion of fluorenone, generated via one-electron reduction, revealing hyperfine coupling constants that reflect delocalization of the unpaired electron over the aromatic π-system, with g-values near 2.003.

Synthesis

Oxidation of fluorene

The oxidation of fluorene (C₁₃H₁₀) to fluorenone (C₁₃H₈O) represents the most common preparative route for this compound, involving the selective conversion of the central to a carbonyl functionality. The general reaction is an aerobic oxidation: \mathrm{C_{13}H_{10} + O_2 \to C_{13}H_8O + H_2O} This process utilizes molecular oxygen as the oxidant, often under controlled conditions to minimize over-oxidation products. Industrial production typically employs catalyzed aerobic oxidation methods, with and salts serving as effective promoters. These reactions are carried out at elevated temperatures of 200–300 °C under air or oxygen , delivering high selectivity and yields exceeding 90%. For instance, the combination of and catalysts facilitates efficient dehydrogenation in the gas phase or liquid media, making it suitable for large-scale synthesis from fluorene-rich fractions. In laboratory settings, oxidation provides a straightforward alternative, where fluorene reacts with (CrO₃) in acetic acid to form fluorenone. The simplified equation is: \mathrm{C_{13}H_{10} + CrO_3 \to C_{13}H_8O + Cr^{3+} + \ byproducts} This method, while generating chromium-containing waste, offers good yields and has been widely used for small-scale preparations due to its simplicity. The oxidation of fluorene has served as the standard route to fluorenone since the early , with methods documented in foundational . Following the reaction, the crude product is typically purified by recrystallization from , which effectively removes impurities and yields analytically pure fluorenone as yellow crystals.

Alternative synthetic routes

Alternative synthetic routes to fluorenone primarily involve non-oxidative strategies that construct the central carbonyl and fused ring system through cyclization or coupling reactions, offering advantages for introducing substituents or avoiding harsh oxidants used in fluorene oxidation. These methods are particularly valuable in settings for synthesizing functionalized analogs, though they are generally less scalable for bulk production compared to direct oxidation due to the need for specialized catalysts or precursors. One established approach is the intramolecular cyclization of biphenyl-2- derivatives via Friedel-Crafts acylation, where the is converted to an and cyclized under acidic conditions to form the fluorenone core. This classic method, typically employing polyphosphoric acid or as the promoter, proceeds through at the position of the unsubstituted phenyl ring, yielding fluorenone in moderate to good efficiency for unsubstituted cases but often requiring harsh conditions that limit compatibility with sensitive substituents. Catalytic variants have improved versatility; for instance, palladium-catalyzed of 2-iodobiphenyl-2'-carboxylic acids uses CO surrogates like phenyl formate, enabling regioselective insertion and cyclization under milder conditions (1 atm , 100°C) with yields up to 90% for electron-neutral substrates. This transient directing group-assisted process activates the C-H bond, forming the five-membered ring via , and tolerates halides and esters better than traditional acid-mediated routes. Intermolecular coupling strategies provide access to diversely substituted fluorenones by assembling the biaryl framework . A notable example is the palladacycle-catalyzed reaction of 2-bromobenzaldehydes with arylboronic acids, which proceeds through sequential , C-H , and carbonyl formation to deliver fluorenones in 60-85% yields. The anionic palladacycle catalyst facilitates of the boronic acid to the , followed by intramolecular palladation and β-hydride elimination to close the ring, making it effective for ortho-substituted arylboronics and avoiding preformed biaryls. Recent advancements post-2020 emphasize sustainable, catalytic methods, including photocatalyzed and metal-free routes that leverage biaryl precursors for efficient core construction. Photocatalyzed deoxygenative cyclization of biphenyl-2-carboxylic acids using complexes and visible light (blue LED, ) generates acyl radicals via single-electron reduction, followed by intramolecular addition and oxidation to afford fluorenones in good to excellent yields, with broad tolerance for electron-withdrawing groups. Metal-free alternatives, such as tert-butyl (TBHP)-promoted cross-dehydrogenative coupling of 2-(aminomethyl)biphenyls, involve generation and cyclization to form highly substituted fluorenones (yields 50-80%) without metals, suitable for late-stage diversification. These diaryl ketone-like precursors enable selective C-C bond formation, often outperforming older methods in step economy for complex analogs. Overall, while these routes excel in precision for substituted fluorenones—offering 70-95% yields in optimized cases—they are less common industrially than fluorene oxidation due to higher catalyst costs and precursor synthesis, but they are increasingly adopted for pharmaceutical intermediates where is paramount.

Chemical reactivity

Reduction reactions

The in fluorenone can undergo partial to form the secondary alcohol fluoren-9-ol, typically achieved using (NaBH₄) in as the solvent. This reaction proceeds via of to the , yielding fluoren-9-ol in high efficiency, with reported yields approaching 95-100%. The balanced equation for the process is: \ce{C13H8O + NaBH4 ->[MeOH] C13H10O + NaB(OH)3 + H2} The resulting fluoren-9-ol exhibits reversible dehydration under acidic conditions, equilibrating back to fluorenone, which underscores the relative stability of the ketone functionality. Complete deoxygenation of fluorenone to fluorene represents a key reduction pathway, often employing the Clemmensen reduction with zinc amalgam and hydrochloric acid. This method converts the carbonyl to a methylene group, as shown: \ce{C13H8O ->[Zn(Hg)/HCl] C13H10 + H2O} The reaction proceeds via carbenoid intermediates and is particularly effective for aromatic ketones like fluorenone, providing fluorene in good yields under conditions in aqueous or alcoholic media. An alternative deoxygenation route is the Wolff-Kishner reduction, involving treatment of fluorenone with followed by base (typically KOH) at elevated temperatures (around 200°C). This hydrazone-mediated also yields fluorene: \ce{C13H8O + N2H4 ->[KOH, \Delta] C13H10 + N2 + H2O} The mechanism involves hydrazone formation and subsequent diazene elimination, making it complementary to the Clemmensen method for acid-sensitive substrates; studies on fluorenone highlight the role of excess in optimizing conversion. Electrochemical reduction offers selective control over fluorenone's carbonyl, generating radical anions or dianions in aprotic solvents like DMF, often at potentials around -1.5 V vs. , which can lead to pinacol-type coupling or further hydrogenation products depending on conditions. Catalytic hydrogenation variants, such as transfer hydrogenation using with catalysts, enable milder to fluorene, achieving high selectivity without gaseous . Regarding stereochemistry, fluoren-9-ol is achiral due to the molecular plane of symmetry passing through the hydroxyl group, the central carbon, and the biphenyl linkage, despite the tetrahedral geometry at C9; however, asymmetric substitution on the fluorene rings in derivatives can introduce chirality, leading to enantioselective outcomes in reductions.

Electrophilic substitutions and derivatizations

Fluorenone undergoes electrophilic aromatic substitution primarily at the 2 and 7 positions on its outer benzene rings, as these sites allow stabilization of the Wheland intermediate through conjugation with the electron-withdrawing carbonyl group at position 9, which overall deactivates the aromatic system but directs substitution to ortho/para-like positions relative to itself. This regioselectivity is evident in nitration reactions, where treatment of fluorenone with a mixture of concentrated sulfuric acid and fuming nitric acid under reflux conditions leads to stepwise introduction of nitro groups, ultimately yielding 2,4,5,7-tetranitrofluorenone in 51–54% yield after recrystallization from acetic acid. The process involves initial mononitration at position 2 (or symmetrically 7), followed by further nitrations at the activated 4 and 5 positions, with the carbonyl enhancing reactivity at these sites despite its deactivating nature. Halogenation follows similar regiochemistry, with bromination occurring selectively at the 2 and 7 positions using in the presence of FeBr₃ as a Lewis acid catalyst. In an environmentally benign , fluorenone is brominated in as the sole solvent, with Br₂ added portionwise over several hours while maintaining neutral via NaOH to neutralize HBr, affording 2,7-dibromofluorenone in 90–98% after simple filtration. This high underscores the directing influence of the carbonyl, which positions the bromine substituents for subsequent derivatizations without significant side reactions at other sites. The functionality of fluorenone also enables direct modifications, such as oxime formation, where reaction with (NH₂OH·HCl) in yields fluoren-9-one in high efficiency under mild heating. This derivative features a coplanar fluorene-oxime system, facilitating applications in further transformations. Additionally, enolization of the under basic conditions allows for coupling reactions, such as aldol condensations with aldehydes, extending the conjugation at the 9-position. Halo-substituted fluorenones, particularly 2,7-dibromofluorenone, serve as versatile precursors for palladium-catalyzed cross-coupling reactions to construct extended π-conjugated systems. In Suzuki-Miyaura couplings, 2,7-dibromofluorenone reacts with aryls in the presence of Pd₂(dba)₃ and P(t-Bu)₃ catalysts, preferentially substituting one bromine atom per equivalent of boronic acid to yield unsymmetrical biaryls in good yields, enhancing electronic properties for optoelectronic materials. Similarly, Heck reactions with alkenes under Pd catalysis introduce vinyl groups at the bromo sites, further elongating the conjugation while preserving the fluorenone core. These derivatizations leverage the electron-withdrawing carbonyl to modulate the reactivity of the leaving groups, enabling precise control over substitution patterns.

Applications and uses

Materials and industrial applications

Fluorenone derivatives play a significant role in , particularly as host materials and emitters in . Their conjugated structure and electron-accepting properties enable efficient charge transport and light emission, making them suitable for and phosphorescent devices. For instance, fluorenone-based thermally activated delayed (TADF) materials have been developed to harvest both singlet and triplet excitons, enhancing efficiency beyond traditional fluorescent emitters. Additionally, derivatives like 3,6-dibromofluorenone serve as intermediates for synthesizing advanced used in layers, contributing to improved device stability and performance. Fluorenone's incorporation into donor-acceptor systems further supports air-stable devices, including , due to its electron-deficient nature. In the field of polymers, fluorenone is integrated into conjugated polymer frameworks to create luminescent materials with applications in optoelectronics and sensing. Polyfluorenone-based systems exhibit strong and high thermal stability, ideal for light-emitting devices and fluorescent probes. For example, Tröger's base-containing fluorenone organic polymers have been synthesized as selective fluorescence sensors for detecting nitroaromatic explosives and metal ions, leveraging changes in upon analyte . These polymers' tunable also enable their use in luminescent films for displays and sensors, where fluorenone units enhance conjugation and responsiveness. Fluorenone-containing compounds are employed in as photosensitizers in dye-sensitized cells (DSSCs), benefiting from their extended conjugation and electron-withdrawing . These derivatives anchor to surfaces, facilitating efficient injection and harvesting. Introducing electron-donating groups, such as triarylamine adjacent to the fluorenone core, broadens spectra and boosts short-circuit current density, leading to power conversion efficiencies up to 4.71% in optimized cells. The structural versatility of fluorenone allows for fine-tuning of energy levels, making it valuable for components beyond DSSCs. Beyond , fluorenone acts as a key intermediate in the industrial synthesis of agrochemicals, including herbicides, where it contributes to the of active aromatic frameworks. Its reactivity supports scalable production of such compounds for agricultural applications.

Biological and pharmaceutical applications

Fluorenone derivatives have garnered attention in pharmaceutical research for their potential therapeutic roles, particularly in and infectious diseases. For instance, thiosemicarbazone derivatives of fluorenone exhibit antitumor activity by inhibiting in various cancer models, with studies demonstrating selective against human cells through mechanisms involving DNA intercalation and inhibition. Similarly, 9-fluorenone-based Schiff bases form metal complexes that enhance anticancer effects, showing reduced tumor growth in preclinical assays via induction. In antiviral applications, bis-basic-substituted fluorenone derivatives like tilorone demonstrate broad-spectrum activity against RNA and DNA viruses by interfering with viral replication pathways, historically used in early interferon induction therapies. Onychine, a naturally occurring 1-methyl-4-azafluorenone alkaloid from Annonaceae plants, exhibits antibiotic properties, particularly against fungal pathogens such as Candida albicans, with minimum inhibitory concentrations as low as 3.12 μg/mL, attributed to disruption of microbial cell membranes. These antimicrobial effects extend to azafluorenone analogs, which show potent activity against Gram-positive bacteria like Staphylococcus aureus and fungi, with structure-activity relationships highlighting the importance of nitrogen substitution for enhanced binding to microbial targets. Neuromodulatory applications of fluorenone derivatives target disorders, such as , through selective inhibition of , an implicated in amyloid-beta aggregation. Novel fluorene-based hybrids act as dual inhibitors of and amyloid-beta, improving cognitive function in animal models of neurodegeneration by modulating signaling. These compounds bind to receptor sites in the , offering potential for treating cognitive decline with reduced side effects compared to non-selective inhibitors. Beyond therapeutics, fluorenone derivatives serve in biological detection methods. 1,8-Diazafluoren-9-one (DFO), a diaza analog, is widely employed in for latent visualization on porous surfaces, where it reacts with in fingerprint residues to form fluorescent products excited by blue-green light, revealing ridge details without damaging the substrate. This reaction proceeds via condensation with primary amines, yielding high-contrast images under UV illumination. In antimalarial research, fluorenone scaffolds contribute to hybrid molecules, such as quinoline-fluorenone conjugates, which inhibit growth by targeting detoxification pathways, with in vitro values in the nanomolar range. Fluorenone-based chemosensors enable detection of metal ions and biomolecules through modulation. Schiff base derivatives of fluorenone act as turn-off sensors for Cu²⁺ ions in aqueous media, exhibiting high selectivity via chelation-induced , with detection limits suitable for environmental and cellular monitoring. These probes also respond to biomolecules like , forming stable complexes that alter emission spectra, facilitating real-time sensing in biological samples. Substitutions at the fluorenone core, such as or groups, enhance these bioactivities by improving and target .

Safety, occurrence, and history

Toxicity and handling

Fluorenone is classified as an eye irritant under regulations (H319), causing serious eye upon direct contact. It may cause mild and poses a potential through dust inhalation, which may lead to . Acute oral is low, with an LD50 greater than 3900 mg/kg in rats, indicating it is not highly via ingestion in single exposures. Chronic exposure effects include possible concerns as an aromatic , though it is not classified as a by major agencies such as IARC or NTP, and unsubstituted fluorenone shows negative results in the Ames mutagenicity test. No significant developmental or data are reported for long-term handling under standard conditions. Environmentally, fluorenone exhibits low solubility (approximately 0.001 g/L), which limits its and acute but contributes to persistence in soil due to adsorption. It is classified as toxic to life with long-lasting effects ( H411), potentially bioaccumulating moderately in organisms (estimated BCF ≈ 310). Safe handling requires wearing protective gloves, , and working in well-ventilated areas to minimize ; avoid and inhalation. Storage should occur in a cool, dry place in tightly closed containers, compatible with flammables but incompatible with strong oxidizing agents to prevent reactions. As of 2025, fluorenone is regulated primarily as an eye irritant (EU H319) with no major international bans, though environmental release is controlled under REACH.

Natural occurrence and historical context

Fluorenone occurs naturally as a minor component in crude oils and sediments, where it arises from the oxidative alteration of fluorene during geological maturation processes. It is also present in pitch and emissions from combustion, often as a derivative of incomplete oxidation of polycyclic aromatic hydrocarbons like fluorene found in . Trace amounts have been detected in environmental matrices such as fly ash from municipal incinerators and wood smoke, reflecting its formation during high-temperature of . The discovery of fluorenone is closely tied to the isolation of its parent compound, fluorene, which was first identified in 1867 by French chemist from heavy coal-tar oils during studies of aromatic hydrocarbons. Fluorenone itself was first synthesized in the early 1900s through the oxidation of fluorene, marking an initial laboratory preparation from coal tar-derived materials around the 1870s to 1890s as chemists explored derivatives of polycyclic aromatics. This oxidation method, typically using or aerial conditions, represented a key early route and linked fluorenone directly to fluorene's natural abundance in fossil fuels. Historically, fluorenone saw limited use in the dye industry by the , where its derivatives contributed to the development of colored pigments and intermediates in coal tar-based colorants, though it remained a niche compound compared to more prominent aromatics like . Interest waned mid-century but resurged in the 2000s with applications in , driven by fluorenone's favorable electronic properties for organic light-emitting diodes (OLEDs) and nonlinear optical materials. A key milestone in the was the synthesis and application of 2,4,5,7-tetranitrofluorenone for forming charge-transfer complexes with aromatic donors, which aided in structural analyses and early studies of molecular interactions. Post-2010, fluorenone derivatives gained attention in bioapplications, including anticancer and antiviral agents due to their DNA-intercalating and inhibitory properties against biological targets. Commercial production of fluorenone primarily involves the oxidation of fluorene extracted from , with global output estimated at several thousand tons annually as of 2025, dominated by Chinese manufacturers such as (1,600 tons/year) and (800 tons/year) for use in and specialty chemicals.

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