Fact-checked by Grok 2 weeks ago

Cyclopentene

Cyclopentene is a cycloalkene with the molecular formula and a molecular weight of 68.12 g/, featuring a five-membered carbon ring containing one carbon-carbon between the first and second carbons. It appears as a colorless with a petrol-like , insoluble in but miscible with solvents, and has a of 0.771 g/mL at 25 °C. Key physical properties include a of 44–46 °C, a of −135 °C, a of 1.421 at 20 °C, and a below 0 °F, making it highly volatile and flammable. Cyclopentene is primarily produced industrially through the selective of or as a in petroleum refining processes, such as thermal cracking of or , where it is distilled from streams. It serves as a versatile intermediate in , particularly in the production of resins, synthetic rubbers, and plastics via or copolymerization with alkenes like or using Ziegler–Natta catalysts. Additional applications include its role in manufacturing agrochemicals, dyestuffs, and pharmaceuticals. Chemically, cyclopentene exhibits typical alkene reactivity, undergoing electrophilic additions, hydrogenation to cyclopentane, and polymerization, while it may react vigorously with strong oxidants or exothermically with reducing agents to evolve hydrogen gas. Safety considerations highlight its extreme flammability, with vapors heavier than air that can travel to ignition sources, and potential as an irritant to eyes, skin, and respiratory tract upon exposure; it poses an aspiration hazard if swallowed and requires handling in well-ventilated areas with appropriate fire suppression measures.

Properties

Physical properties

Cyclopentene has the molecular formula and a of 68.12 g/mol. It is a colorless at , exhibiting a sweet, petroleum-like . Key physical constants include a of 0.771 g/cm³ at 25 °C, a of −135 °C, a of 44–46 °C, and a below −34 °C (−30 °F). These properties indicate that cyclopentene is a volatile, low-boiling suitable for handling as a under ambient conditions but requiring precautions due to its high flammability.
PropertyValueConditionsSource
Density0.771 g/cm³25 °CSigma-Aldrich
Melting point−135 °C-ChemicalBook
Boiling point44–46 °C760 mmHgSigma-Aldrich
Flash point< −34 °CClosed cupChemicalBook
Cyclopentene is practically immiscible with water, with a solubility of 0.535 g/L at 25 °C, but it dissolves readily in common organic solvents such as ethanol and diethyl ether. The refractive index is 1.421 (n²⁰/D).

Chemical properties

Cyclopentene is classified as a cycloalkene featuring a five-membered ring with one endocyclic carbon-carbon double bond between carbons 1 and 2. This structural arrangement results in moderate ring strain, primarily arising from torsional strain and slight deviations from ideal bond angles in the puckered envelope conformation of the ring. The allylic C-H bonds in cyclopentene exhibit weak acidity, with a pKa of about 43, comparable to other allylic positions in simple alkenes due to resonance stabilization of the resulting carbanion. Regarding stability, the molecule displays enhanced reactivity relative to acyclic alkenes like owing to the ring strain, which lowers the activation energy for reactions involving bond breaking in the ring; however, it is less strained and thus less reactive than highly strained analogs such as . Cyclopentene is susceptible to polymerization initiated by acidic or radical conditions, reflecting its moderate thermodynamic drive toward ring-opening processes. Thermodynamically, the standard enthalpy of formation (Δ_f H°) for gaseous cyclopentene is 32.6 kJ/mol at 298 K. The heat of combustion for the liquid phase is -3115 kJ/mol, indicating a relatively high energy content consistent with its strained structure. Spectroscopically, the infrared spectrum features a characteristic C=C stretching absorption at around 1640 cm⁻¹, shifted slightly from the typical 1660 cm⁻¹ for acyclic alkenes due to ring constraints. In the ¹H NMR spectrum, the two vinylic protons appear as a multiplet at 5.6–5.7 ppm, reflecting their equivalent positions and coupling to adjacent methylene groups.

Synthesis

Historical methods

Cyclopentene was first prepared in 1893 by Carl Gärtner through the dehydrohalogenation of iodocyclopentane using potassium hydroxide in ethanol, resulting in the compound he termed "pentamethenylene." In the early 20th century, alternative methods emerged, such as the dehalogenation of dibromocyclopentane with zinc dust, which provided a route to the alkene from the corresponding vicinal dihalide precursor. These historical routes suffered from significant limitations, including low yields and the necessity for multi-step halogenation of cyclopentane or its derivatives to access the required starting materials.

Industrial production

Cyclopentene is primarily produced on an industrial scale as a by-product during the steam cracking of naphtha or other petroleum fractions at temperatures between 750°C and 900°C. This thermal cracking process generates a complex mixture of hydrocarbons, including a C5 fraction where cyclopentene is present alongside other components such as cyclopentadiene, isoprene, and piperylene. Following the cracking step, cyclopentene is recovered from the crude C5 stream through a series of separation processes. Cyclopopentadiene is first selectively extracted or dimerized to dicyclopentadiene, which is removed via distillation due to its higher boiling point, leaving a raffinate containing cyclopentene. The cyclopentene is then isolated by fractional distillation under carefully controlled conditions to achieve the desired purity. Global annual production of cyclopentene is estimated at approximately 15,000–20,000 metric tons as of 2024, primarily driven by petrochemical operations in regions with significant naphtha cracking capacity. An alternative industrial route involves the partial hydrogenation of cyclopentadiene, which is abundant in the same C5 fractions from steam cracking. This selective hydrogenation employs catalysts such as palladium on carbon (Pd/C) or Pd/Al₂O₃ under mild conditions, typically at 25-50°C and 1-5 atm of hydrogen pressure, to minimize over-hydrogenation to cyclopentane. The reaction achieves high selectivity (>90%) toward cyclopentene, with the product subsequently purified. Industrial-grade cyclopentene requires a purity of greater than 95%, with common impurities like (boiling point 49.3°C) and residual diolefins removed via exploiting the slight difference in boiling points (cyclopentene: 44.2°C). This purification ensures suitability for downstream applications while maintaining economic viability in large-scale operations.

Laboratory preparation

Cyclopentene is commonly prepared in the laboratory through the of , a secondary , using acid catalysts that promote the elimination of . The reaction is typically conducted by heating cyclopentanol with concentrated (H₂SO₄) at 100–150°C, following an E1 involving formation and subsequent . Yields of 70–90% are achievable under optimized conditions, making this a straightforward and efficient for small-scale synthesis. \mathrm{C_5H_9OH \xrightarrow{H_2SO_4, 100-150^\circ C} C_5H_8 + H_2O} An alternative dehydration approach employs phosphorus oxychloride (POCl₃) in pyridine, which facilitates an E2 elimination mechanism at milder temperatures (around 0–25°C), minimizing side reactions such as isomerization and providing cyclopentene in high purity suitable for research applications. This method is particularly useful when avoiding harsh acidic conditions is desirable. Selective reduction of represents another versatile laboratory route to cyclopentene, focusing on adding one equivalent of to yield the monoene with high specificity. , RhCl(PPh₃)₃, enables this transformation in solvents like or under mild pressure (1–3 ) at , achieving greater than 95% selectivity for cyclopentene over the fully saturated . A classical alternative involves (Na/Hg) in , which performs the partial reduction via dissolving metal , also attaining >95% selectivity and yields up to 80% on scales below 1 kg. Cyclopentene can also be synthesized via base-promoted elimination from cyclopentyl halides (e.g., bromide or chloride) or tosylates, leveraging the E2 mechanism for clean double-bond formation. Treatment with a strong, non-nucleophilic base such as sodium hydroxide (NaOH) in aqueous ethanol or 1,8-diazabicyclo[5.4.0]undec-7-ene (DBU) in dimethyl sulfoxide (DMSO) at 50–80°C proceeds rapidly, delivering cyclopentene in 70–85% yield with minimal byproducts, ideal for preparing isotopically labeled variants. A contemporary laboratory variant utilizes palladium-catalyzed dehydrogenation of cyclopentane, conducted at approximately 300°C with Pd supported on alumina or carbon under inert atmosphere, offering a direct dehydrogenative route with conversions up to 50% per pass and selectivity exceeding 90% for cyclopentene. This method highlights the adaptability of transition-metal catalysis for high-purity alkene production in research settings.

Reactions

Addition reactions

Cyclopentene, as a cyclic alkene, undergoes typical electrophilic addition reactions at its double bond, leading to saturated derivatives while preserving the five-membered ring structure. These reactions exploit the nucleophilic nature of the π-bond, allowing for the incorporation of various electrophiles and nucleophiles. In halogenation, cyclopentene reacts with bromine in carbon tetrachloride to form trans-1,2-dibromocyclopentane through an anti addition mechanism involving a bromonium ion intermediate. The reaction proceeds stereospecifically, yielding the trans product exclusively due to backside attack by the bromide ion on the cyclic halonium species. Hydrogenation of cyclopentene involves the catalytic addition of gas using or catalysts, converting it quantitatively to under mild conditions such as 1 atm pressure and . This syn addition saturates the double bond, with yields often exceeding 95% in standard protocols. Hydrohalogenation of cyclopentene with follows , adding the to one of the equivalent sp² carbons and to the other, resulting in chlorocyclopentane. Due to the symmetry of the , no issues arise, and the reaction typically requires no catalyst, proceeding via a intermediate. Oxymercuration-demercuration provides a method for hydration without carbocation rearrangements, where cyclopentene reacts with mercury(II) acetate in water followed by sodium borohydride reduction to yield cyclopentanol via anti addition. This process ensures Markovnikov orientation with high stereoselectivity, often achieving over 95% retention in cyclic systems like cyclopentene. Palladium-catalyzed hydrocarboxylation of cyclopentene incorporates carbon monoxide and water to form cyclopentanecarboxylic acid, a linear addition across the double bond enabled by ligands such as dppf in an aqueous medium. This method operates under mild conditions (e.g., 80°C, 10 bar CO) and demonstrates broad substrate tolerance for cyclic alkenes.

Polymerization

Cyclopentene undergoes via , typically employing TiCl₄ activated by AlEt₃, to yield syndiotactic polycyclopentene characterized by a of 1,2- and 3,1-linkages in the backbone. These linkages arise from the insertion of the cyclopentene into the growing metal-carbon bond, with the 3,1-enchainment involving at the allylic position followed by migration. The resulting exhibits high stereoregularity and achieves molecular weights ranging from 10⁵ to 10⁶ , contributing to its mechanical strength. Ring-opening metathesis (ROMP) of cyclopentene proceeds with ruthenium-based Grubbs' catalysts, such as the first-generation benzylidene complex, generating polypentenamer with alternating double bonds in the main chain. This process involves carbene-mediated ring opening and cross-metathesis, though cyclopentene's low limits conversion compared to more strained analogs like ; related derivatives, such as those from , form polydicyclopentadiene via similar mechanisms. The equilibrium nature of the reaction often requires removal of to drive forward. Radical polymerization of cyclopentene is less prevalent due to the monomer's moderate reactivity and tendency toward , but it can be initiated by such as benzoyl peroxide at 60–80°C, producing atactic polycyclopentene with irregular and reduced thermal stability relative to coordinated analogs. These polymers typically exhibit lower molecular weights and broader polydispersity, limiting their practical utility. The polymers derived from cyclopentene, particularly via ROMP, display elastomeric behavior with a glass transition temperature around −50°C, enabling flexibility at low temperatures and potential use in tire treads for enhanced grip and durability. The general polymerization reaction is represented as: n \ce{C5H8 ->[catalyst] (C5H8)_n} This equation encompasses both addition and ring-opening pathways, where the repeating unit retains the C₅H₈ composition.

Other transformations

Cyclopentene undergoes allylic oxidation with (SeO₂) in solvents such as dioxane or to produce cyclopent-2-en-1-ol as the primary product. This reaction exploits the relative weakness of the allylic C-H bond, leading to selective oxidation at the allylic position without affecting the . Further oxidation under controlled conditions can convert the allylic to 2-cyclopenten-1-one. Allylic bromination of cyclopentene is achieved using N-bromosuccinimide (NBS) in the presence of light or a radical initiator like benzoyl , yielding 3-bromocyclopentene as the major product. \ce{C5H8 + NBS -> 3-bromocyclopentene + HBr} This radical process involves abstraction of the allylic hydrogen, forming a resonance-stabilized allylic radical intermediate that reacts with bromine, and is highly selective due to the low concentration of Br₂ generated from NBS. Ozonolysis of cyclopentene involves addition of ozone (O₃) across the double bond to form a primary ozonide, which rearranges to a secondary ozonide. Subsequent reductive workup with dimethyl sulfide (DMS) or zinc in acetic acid cleaves the ozonide to succindialdehyde (butanedial). \ce{C5H8 + O3 ->{{grok:render&&&type=render_inline_citation&&&citation_id=1&&&citation_type=wikipedia}} ozonide ->{{grok:render&&&type=render_inline_citation&&&citation_id=2&&&citation_type=wikipedia}} OHC-CH2-CH2-CHO} This transformation completely severs the carbon-carbon double bond, providing a key method for ring cleavage in synthetic applications. Cyclopentene engages in olefin cross-metathesis reactions with terminal alkenes, catalyzed by the Hoveyda-Grubbs second-generation ruthenium complex, resulting in ring-opening cross-metathesis (ROCM) products such as functionalized dienes. These reactions proceed via a metal carbene mechanism, exchanging alkylidene groups and releasing ethylene as a byproduct, and are tolerant of various functional groups on the terminal alkene partner. Pyrolysis of cyclopentene at approximately 500°C induces thermal decomposition through unimolecular pathways, primarily yielding ethylene, propylene, and hydrogen as fragmentation products, alongside minor amounts of cyclopentadiene. This process is studied for insights into reaction mechanisms, including biradical intermediates and C-C bond cleavages, under gas-phase homogeneous conditions.

Uses and applications

Industrial uses

Cyclopentene serves as a minor component in gasoline, typically comprising 0.12–0.18% by volume in standard formulations. This presence arises from petroleum refining processes, where it forms part of the C5 hydrocarbon fraction. In the synthetic rubber industry, cyclopentene acts as a key feedstock for polymerization reactions that yield cyclopentene-based elastomers. These materials exhibit properties suitable for applications in tires, hoses, and other rubber products, with the sector accounting for approximately 70% of global cyclopentene demand. Such elastomers benefit from the ring structure of cyclopentene, providing enhanced flexibility and durability compared to some traditional rubbers. Cyclopentene finds use as a in specialty formulations for paints and adhesives, owing to its low of 44 °C and ability to dissolve non-polar substances effectively. This property allows for controlled evaporation in coating applications, improving process efficiency in industrial settings. Globally, cyclopentene is primarily obtained as a from C5 streams in petrochemical cracking operations, with market demand closely linked to broader production volumes. The compound's annual global market value was approximately US$28 million as of 2024, reflecting its niche but essential role in .

Synthetic applications

Cyclopentene is widely employed as a versatile intermediate in the synthesis of , where of its in precursors such as yields dialdehydes essential for constructing the characteristic five-membered ring systems found in pharmaceutical agents like . This approach leverages the ring's reactivity to introduce the α- and ω-side chains typical of prostaglandin structures, enabling efficient assembly of bioactive molecules with applications in reproductive health and gastrointestinal treatments. In synthesis, cyclopentene acts as a precursor to through oxidation, producing scaffolds that are incorporated into herbicides and other pesticides. These derivatives exhibit enhanced reactivity for further conjugation with heterocyclic moieties, contributing to compounds that inhibit enzymes or disrupt metabolic pathways in weeds, as seen in the design of novel agents. Cyclopentene's hydrogenation followed by amination yields cyclopentylamine derivatives, which are functionalized in pharmaceutical routes to produce antihistamines and antiviral agents.