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C5H10

C5H10 is the molecular formula for a class of ten constitutional isomers consisting of hydrocarbons with five carbon atoms and one , which can manifest as either a carbon-carbon in acyclic structures (alkenes) or a saturated ring in cyclic structures (cycloalkanes). These isomers include five alkenes—1-pentene, 2-pentene, 2-methylbut-1-ene, 3-methylbut-1-ene, and 2-methylbut-2-ene—and five cycloalkanes: , methylcyclobutane, ethylcyclopropane, 1,1-dimethylcyclopropane, and 1,2-dimethylcyclopropane. Some of these, such as 2-pentene and 1,2-dimethylcyclopropane, exhibit geometric (/ or /) stereoisomerism, resulting in a total of thirteen distinct stereoisomers. The isomers are significant in industrial applications, serving as components in and being generated as by-products during the catalytic cracking of . For instance, 1-pentene is a colorless liquid used in and as a comonomer in production. Among the cycloalkanes, is a volatile, colorless liquid employed as a , blowing agent for foams, and precursor in the synthesis of for production. These C5H10 isomers share physical properties typical of small hydrocarbons, such as low boiling points and flammability, but vary in reactivity based on their structure; alkenes undergo addition reactions, while cycloalkanes are relatively inert but can participate in ring-opening processes under certain conditions. Their study is fundamental in for understanding isomerism and unsaturation.

Fundamentals

Molecular Formula

The molecular formula C₅H₁₀ represents a class of hydrocarbons composed of exactly five carbon atoms and ten hydrogen atoms, where the carbon atoms form a framework bonded to hydrogen atoms to satisfy the tetravalency of carbon, requiring each carbon to complete four covalent bonds. In contrast to fully saturated alkanes with the general formula CₙH₂ₙ₊₂ (such as , C₅H₁₂, featuring only single bonds), the C₅H₁₀ formula indicates an adjustment for one , which could arise from a or a ring structure while maintaining the overall composition. This formula emerged from early 19th-century studies of compounds, where hydrocarbons were isolated and analyzed to determine their elemental composition, building on foundational work in . The empirical formulas of such compounds, including those like C₅H₁₀, were confirmed through techniques perfected by in the 1830s, which involved oxidizing the sample to measure carbon and hydrogen content via the quantities of and produced. Under the International Union of Pure and Applied Chemistry (IUPAC) for hydrocarbons, the prefix "pent-" specifically denotes a chain or structure with five carbon atoms, serving as the base for naming compounds with this molecular , such as or .

The (DU), also known as the index of hydrogen deficiency, quantifies the number of rings and/or multiple bonds in a relative to its saturated counterpart. It is calculated using the \text{DU} = \frac{2C + 2 - H - X + N}{2}, where C is the number of carbon atoms, H is the number of hydrogen atoms, X is the number of halogen atoms, and N is the number of nitrogen atoms. For the molecular formula C5H10, which contains no halogens or nitrogen atoms, the calculation yields DU = (2 × 5 + 2 - 10)/2 = 1. This value indicates a single site of unsaturation, meaning the possible isomers incorporate either one carbon-carbon double bond (characteristic of alkenes) or one ring (characteristic of cycloalkanes), but cannot feature both, a triple bond, or multiple unsaturations without altering the formula. By comparison, the fully saturated with five carbons, (C5H12), has DU = 0, reflecting the general formula CnH2n+2 for acyclic alkanes. The loss of two hydrogen atoms in C5H10 thus accounts for the single . This DU value underpins the classification of C5H10 isomers, limiting possibilities to structures with exactly or and excluding those with higher unsaturation levels. In total, there are 13 distinct isomers (including stereoisomers), divided into 6 alkenes and 7 cycloalkanes.

Alkenes

Straight-Chain Isomers

The straight-chain isomers of C5H10 as alkenes are the pentenes, characterized by a linear five-carbon chain with , consistent with the for this formula. These include 1-pentene and 2-pentene, where the position of the determines the distinct structures. 1-Pentene has the structure CH₂=CH-CH₂-CH₂-CH₃, with the IUPAC name pent-1-ene and number 109-67-1. It has a of 30 °C and a of 0.64 g/cm³. This compound is produced industrially as a of the catalytic or cracking of fractions. In reactions, such as with hydrogen halides, 1-pentene follows , where the hydrogen adds to the less substituted carbon of the , leading to regioselective formation of 2-halopentane as the major product. Industrially, 1-pentene serves as a comonomer in the copolymerization of to produce (LLDPE), contributing to improved flexibility and strength in the resulting polymer. 2-Pentene has the general structure CH₃-CH=CH-CH₂-CH₃ and exists as geometric s due to restricted rotation around the carbon-carbon , which prevents free interconversion between configurations. The (E)-isomer, or -2-pentene (IUPAC name (E)-pent-2-ene, 646-04-8), has a of 36.3 °C, while the (Z)-isomer, or cis-2-pentene (IUPAC name (Z)-pent-2-ene, 627-20-3), has a higher of 37.9 °C. The isomer is more stable than the cis isomer owing to reduced steric hindrance between the methyl and ethyl groups across the double bond. In contrast to 1-pentene, reactions to 2-pentene lack under Markovnikov conditions because the carbons are equivalently substituted, yielding a of 2- and 3-halopentanes. A hypothetical 3-pentene would be identical to 2-pentene due to the symmetry of the linear carbon chain, where numbering the double bond from either end yields the same structure; thus, no distinct 3-pentene isomer exists.

Branched-Chain Isomers

The branched-chain isomers of C5H10 consist of methyl-substituted butene structures, which introduce nonlinearity compared to straight-chain pentenes and influence physical properties and reactivity. These isomers lack geometric stereoisomers in most cases due to symmetric substitution patterns around the double bond. One key is 3-methylbut-1-ene, with the (CH₃)₂CHCH=CH₂ and number 563-45-1. Its is 20°C, lower than that of straight-chain analogs like 1-pentene due to reduced surface area from branching. This exhibits high reactivity in electrophilic additions, as the is less substituted and more accessible to nucleophiles. Another , 2-methylbut-1-ene, features the CH₂=C(CH₃)CH₂CH₃ and number 563-46-2. It has a of 31°C and no stereoisomers, owing to the terminal =CH₂ group that prevents E/Z isomerism. The methyl substitution at the contributes to its moderate stability relative to other terminals. The third major branched isomer is 2-methylbut-2-ene, with structure (CH₃)₂C=CHCH₃ and CAS number 513-35-9. Its is 38°C, reflecting increased intermolecular forces from the more compact, internal . This trisubstituted shows no E/Z stereoisomerism because one carbon of the bears two identical methyl groups, and it is more stable than terminal alkenes due to greater alkyl substitution that hyperconjugates with the π bond. In electrophilic additions, such as with HBr, it preferentially forms a tertiary intermediate, enhancing reaction selectivity toward the more substituted carbon. Branching in these C5H10 alkenes generally results in slightly varied points influenced by molecular , with more internal and substituted structures like 2-methylbut-2-ene exhibiting higher values than highly branched terminals due to enhanced van der Waals interactions despite reduced chain linearity. These isomers are primarily obtained from , such as catalytic or thermal cracking of higher hydrocarbons, where 2-methylbut-2-ene often predominates in C5 fractions from .

Cycloalkanes

Five-Membered Ring Isomers

is the sole unsubstituted five-membered ring isomer of C5H10, featuring a monocyclic structure composed of five methylene () groups arranged in a ring, which can be represented as ()4. Its systematic IUPAC name is , and it is identified by 287-92-3. Key physical properties include a of 49.3 °C, a of -93.9 °C, and a of 0.75 g/cm³ at 20 °C. The molecule adopts a puckered envelope conformation rather than a fully planar ring to reduce torsional strain, with C-C-C bond angles averaging approximately 108°, closely approaching the ideal tetrahedral angle of 109.5° and resulting in minimal angle strain. This near-optimal geometry contributes to its relative stability among smaller cycloalkanes, as evidenced by a standard heat of combustion of 793.5 kcal/mol. Cyclopentane is typically synthesized via catalytic hydrogenation of cyclopentene using hydrogen gas and a metal catalyst such as platinum or palladium, though it can also be obtained industrially by high-temperature cracking of cyclohexane over alumina. Dehydration of cyclopentanol yields cyclopentene as an intermediate, which is then hydrogenated to cyclopentane. In practical applications, serves as a nonpolar solvent for resins, waxes, and oils in and processes, and as a minor component in to enhance fuel properties. It is generally non-toxic with low acute hazards but is highly flammable, with a of -37 °C. Due to its high symmetry and lack of substituents, exhibits no stereoisomers, precluding the possibility of / configurations.

Four-Membered Ring Isomers

Methylcyclobutane is the sole four-membered isomer of C5H10, consisting of a cyclobutane with a attached to one of the carbons. Its IUPAC name is methylcyclobutane, with the C5H10 and 598-61-8. The compound has a of 36.9 °C and a of 0.77 g/cm³ at 20 °C. The exhibits significant due to its small size. The C-C-C bond angles in the cyclobutane are approximately 90°, deviating from the ideal tetrahedral angle of 109.5° and resulting in an angle strain of about 20° per bond. This contributes to a total of approximately 26 kcal/mol, similar to that of unsubstituted cyclobutane. To minimize torsional strain, methylcyclobutane adopts a puckered conformation rather than a planar one, in which the occupies a pseudo-equatorial position. Methylcyclobutane can be synthesized through reactions of cyclobutane, typically involving or catalytic processes to introduce the , or via ring expansion of substituted cyclopropanes such as methylcyclopropane, where insertion of a methylene unit enlarges the three-membered ring. Due to its elevated , methylcyclobutane is more reactive than , facilitating reactions such as hydrogenolysis and with higher exothermicity compared to larger cycloalkanes. It undergoes more readily under catalytic conditions, often initiated by transition metals like , leading to linear polymers via C-C bond cleavage. Methylcyclobutane lacks stereoisomers, as the single methyl substituent on the symmetric cyclobutane ring does not allow for or chiral centers in its puckered conformation.

Three-Membered Ring Isomers

The three-membered ring isomers of C5H10 consist of derivatives with alkyl substituents that satisfy the molecular formula while maintaining the characteristic high of the parent . These include ethylcyclopropane, 1,1-dimethylcyclopropane, and the stereoisomers of 1,2-dimethylcyclopropane. Due to the compressed 60° bond angles in the ring—far from the ideal tetrahedral 109.5°—these compounds exhibit significant angle strain, contributing to their total of approximately 27-28 kcal/mol, comparable to unsubstituted . This strain arises primarily from the deviation in bond angles and partial eclipsing of hydrogens, rendering the ring highly reactive toward and ring-opening reactions. Ethylcyclopropane features a ring substituted with an (-CH₂CH₃) at one carbon. Its IUPAC name is ethylcyclopropane, with number 1191-96-4. The compound has a boiling point of approximately 36.5-37°C and retains much of the of the parent , around 28 kcal/, due to the unaltered ring geometry. The substitution introduces minimal additional , allowing for relatively straightforward isolation and study. 1,1-Dimethylcyclopropane possesses a ring with two methyl groups attached to the same carbon, creating a disubstitution pattern that increases local crowding around the substituted vertex. Its IUPAC name is 1,1-dimethylcyclopropane, and the number is 1630-94-0. This boils at about 21°C, lower than ethylcyclopropane due to its more compact structure and reduced surface area for intermolecular forces. The methyl groups exacerbate steric compression within the strained ring, though the overall remains in the 27-30 kcal/ range typical for alkylcyclopropanes. 1,2-Dimethylcyclopropane has methyl groups on adjacent carbons, leading to and stereoisomers. The isomer, (1R,2S)-1,2-dimethylcyclopropane (CAS 930-18-7), is achiral (meso) due to its plane of symmetry, while the isomer exists as a pair of enantiomers: (1R,2R)-1,2-dimethylcyclopropane and (1S,2S)-1,2-dimethylcyclopropane (CAS 2402-06-4 for the racemate). The form has a of 37°C, slightly higher than the trans at 28-32°C, reflecting differences in molecular packing. The isomer experiences greater steric repulsion between the proximal methyl groups, resulting in higher strain compared to the trans, though both maintain the inherent of ~27 kcal/mol. These isomers share extreme angle that imparts high reactivity, such as facile ring opening with to yield bromoalkanes via electrophilic attack on the strained C-C bonds. They are commonly synthesized using the Simmons-Smith reaction, which employs and zinc-copper couple to cyclopropanate suitable alkenes or dienes, preserving from the precursor. Compared to larger ring cycloalkanes, the escalated in these three-membered variants promotes greater propensity for thermal and catalytic rearrangements.