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Właściwości Glucal

Właściwości Glucal (C6H10O4):

Nazwa związkuGlucal
Wzór chemicznyC6H10O4
Masa Molowa146.1412 g/mol

Struktura chemiczna
C6H10O4 (Glucal) - Struktura chemiczna
Struktura Lewisa
Struktura molekularna 3D
Właściwości fizyczne
Wyglądbiałe kryształy w formie pryzmatów jednoskośnych
ZapachBezwonny
Rozpuszczalność14.0 g/100 ml
Gęstość1.3600 g/cm³
Hel 0.0001786
Iryd 22.562
Topnienia152.10 °C
Hel -270.973
Węglik hafnu 3958
Wrzenie337.50 °C
Hel -268.928
Węglik wolframu 6000
Termochemia
Entalpia formowania-994.30 kJ/mol
Kwas adypinowy -994.3
Trikarbon 820.06

Skład pierwiastkowy C6H10O4
PierwiastekSymbolMasa atomowaAtomyProcent masowy
WęgielC12.0107649.3114
WodórH1.00794106.8970
TlenO15.9994443.7916
Skład procentowy masySkład procentowy atomowy
C: 49.31%H: 6.90%O: 43.79%
C Węgiel (49.31%)
H Wodór (6.90%)
O Tlen (43.79%)
C: 30.00%H: 50.00%O: 20.00%
C Węgiel (30.00%)
H Wodór (50.00%)
O Tlen (20.00%)
Skład procentowy masy
C: 49.31%H: 6.90%O: 43.79%
C Węgiel (49.31%)
H Wodór (6.90%)
O Tlen (43.79%)
Skład procentowy atomowy
C: 30.00%H: 50.00%O: 20.00%
C Węgiel (30.00%)
H Wodór (50.00%)
O Tlen (20.00%)
Identyfikatory
Numer CAS124-04-9
UŚMIECHÓWO=C(O)CCCCC(=O)O
UŚMIECHÓWC(CCC(=O)O)CC(=O)O
Formuła HillaC6H10O4

Związki pokrewne
FormułaNazwa złożona
CHOKwas kolanowy
CH2OFormaldehyd
H2CO3Kwas węglowy
C3H8OPropanol
CH2COKeten
C4H8OTetrahydrofuran
CH3OHMetanol
CH2O2Kwas mrówkowy
C3H6OAldehyd propionowy
C7H8OAnizol

Przykładowe reakcje dla C6H10O4
RównanieTyp reakcji
C6H10O4 + O2 = CO2 + H2Ospalanie

Powiązany
Kalkulator masy cząsteczkowej
Kalkulator stopnia utlenienia

Adipic Acid (C₆H₁₀O₄): Chemical Compound

Scientific Review Article | Chemistry Reference Series

Abstract

Adipic acid, systematically named hexanedioic acid with molecular formula C₆H₁₀O₄, represents the most industrially significant dicarboxylic acid with annual global production exceeding 2.5 billion kilograms. This aliphatic dicarboxylic acid crystallizes as white monoclinic prisms with melting point 152.1 °C and boiling point 337.5 °C. The compound exhibits characteristic dibasic acid behavior with pKa values of 4.43 and 5.41. Primary industrial application involves polycondensation with hexamethylenediamine to produce nylon-6,6, accounting for approximately 60% of global consumption. Additional applications include plasticizer production, polyurethane synthesis, and food additive utilization as acidulant E355. The compound demonstrates limited aqueous solubility (24 g/L at 25 °C) but high solubility in polar organic solvents including ethanol and methanol.

Introduction

Adipic acid, classified as an organic dicarboxylic acid, occupies a position of considerable industrial importance within modern chemical manufacturing. Auguste Laurent first isolated the compound in 1837 through nitric acid oxidation of various fats via sebacic acid intermediate, deriving its name from the Latin "adeps" meaning animal fat. The compound's structural configuration features two terminal carboxylic acid groups separated by four methylene units, creating an optimal molecular geometry for polycondensation reactions. Industrial significance emerged following Wallace Carothers' pioneering work on polyamides at DuPont during the 1930s, establishing adipic acid as the fundamental monomer for nylon-6,6 production. Current manufacturing processes predominantly utilize catalytic oxidation of cyclohexanol-cyclohexanone mixtures, though alternative synthetic routes continue to undergo development.

Molecular Structure and Bonding

Molecular Geometry and Electronic Structure

The adipic acid molecule adopts an extended zig-zag conformation in the solid state with all carbon atoms residing in approximate coplanar arrangement. X-ray crystallographic analysis reveals monoclinic crystal structure with space group P2₁/c and unit cell parameters a = 9.72 Å, b = 5.34 Å, c = 10.91 Å, and β = 99.5°. The central carbon atoms exhibit sp³ hybridization with characteristic tetrahedral geometry and C-C-C bond angles measuring approximately 112°. Terminal carboxylic acid groups demonstrate planar configuration with C-C-O bond angles of 124° and O-C-O angles of 126°. The four methylene groups separating carboxyl functions create an optimal distance for intramolecular interactions, with carbon-carbon bond lengths measuring 1.54 Å and carbon-oxygen bonds measuring 1.36 Å in carboxyl groups.

Chemical Bonding and Intermolecular Forces

Adipic acid molecules engage in extensive hydrogen bonding networks within crystalline structures. Each carboxylic acid group participates as both hydrogen bond donor and acceptor, forming dimeric associations through O-H···O interactions with bond distances of 2.64 Å. These dimeric units further interconnect through additional hydrogen bonds along the crystal lattice, creating a three-dimensional network. The molecular dipole moment measures 2.7 D in solution, reflecting the polar nature of carboxylic acid functionalities. Van der Waals interactions between methylene groups contribute to crystal stability and influence melting characteristics. The separation between carboxyl groups prevents intramolecular hydrogen bonding while facilitating intermolecular associations that dominate solid-state properties.

Physical Properties

Phase Behavior and Thermodynamic Properties

Adipic acid presents as white crystalline powder or monoclinic prisms with density 1.360 g/cm³ at 25 °C. The compound undergoes sharp melting at 152.1 °C with heat of fusion 45.9 kJ/mol. Boiling occurs at 337.5 °C with heat of vaporization 98.4 kJ/mol. Sublimation becomes significant above 100 °C with vapor pressure 0.097 hPa at 18.5 °C. Specific heat capacity measures 1.46 J/g·K at 25 °C. Aqueous solubility demonstrates strong temperature dependence: 14 g/L at 10 °C, 24 g/L at 25 °C, and 1600 g/L at 100 °C. The compound exhibits high solubility in polar organic solvents including methanol, ethanol, and acetone, but negligible solubility in non-polar solvents such as benzene and petroleum ether. Viscosity measures 4.54 cP at 160 °C in molten state.

Spectroscopic Characteristics

Infrared spectroscopy reveals characteristic carbonyl stretching vibrations at 1705 cm⁻¹ and broad O-H stretching absorption between 2500-3300 cm⁻¹. C-H stretching appears at 2950 cm⁻¹ while C-O stretching and O-H bending vibrations occur at 1280 cm⁻¹ and 1420 cm⁻¹ respectively. Proton NMR spectroscopy in DMSO-d₆ displays triplet signals at δ 2.18 ppm for methylene protons adjacent to carboxyl groups and complex multiplet at δ 1.58 ppm for central methylene protons. Carboxylic acid protons appear as broad singlet at δ 12.0 ppm. Carbon-13 NMR shows carbonyl carbon resonance at δ 174.5 ppm, α-methylene carbon at δ 33.8 ppm, and inner methylene carbons at δ 24.3 ppm. UV-Vis spectroscopy indicates no significant absorption above 210 nm due to absence of chromophoric groups.

Chemical Properties and Reactivity

Reaction Mechanisms and Kinetics

Adipic acid undergoes characteristic reactions of aliphatic dicarboxylic acids including esterification, amidation, and salt formation. Esterification reactions proceed with rate constant k = 2.4 × 10⁻⁴ L/mol·s in ethanol at 25 °C. The compound demonstrates thermal stability up to 200 °C, above which decarboxylation occurs yielding cyclopentanone through intramolecular ketonization. This reaction proceeds efficiently with barium hydroxide catalyst at 285 °C with 85% yield. Reaction with thionyl chloride produces adipoyl chloride, an important intermediate for polymer synthesis. Polycondensation with diamines represents the most significant chemical transformation, proceeding through step-growth polymerization mechanism with activation energy 85 kJ/mol. The reaction follows second-order kinetics with respect to acid and amine concentrations.

Acid-Base and Redox Properties

Adipic acid behaves as a typical dibasic acid with dissociation constants pKa₁ = 4.43 and pKa₂ = 5.41 at 25 °C. The relatively small difference between pKa values indicates limited electrostatic interaction between carboxylate groups. Buffer capacity maximizes in pH range 3.4-6.4 with maximum buffering intensity at pH 4.92. Titration with strong base produces two distinct inflection points at half-equivalence points pH 4.43 and pH 5.41. The compound exhibits no significant redox activity under standard conditions, with oxidation requiring strong oxidizing agents such as potassium permanganate or nitric acid. Electrochemical reduction does not occur within the water stability window, reflecting the saturated nature of the carbon chain.

Synthesis and Preparation Methods

Laboratory Synthesis Routes

Laboratory synthesis of adipic acid typically proceeds through oxidation of cyclohexene using potassium permanganate or ozone. The permanganate oxidation proceeds in aqueous solution at 80-90 °C with yields exceeding 70%. Ozonolysis of cyclohexene in dichloromethane followed by oxidative workup with hydrogen peroxide provides adipic acid in 65% yield. Alternative laboratory routes include hydrolysis of adiponitrile with concentrated hydrochloric acid at reflux temperature, yielding adipic acid after recrystallization from water. Hydrogenation of muconic acid using palladium on carbon catalyst represents another viable laboratory method, particularly for isotopically labeled compounds. Purification typically involves recrystallization from hot water or ethanol-water mixtures, producing material with purity exceeding 99.5%.

Analytical Methods and Characterization

Identification and Quantification

Adipic acid identification routinely employs infrared spectroscopy with characteristic carbonyl stretching at 1705 cm⁻¹ providing definitive confirmation. Melting point determination at 152.1 °C serves as preliminary identification method. High-performance liquid chromatography with UV detection at 210 nm enables quantitative analysis using reverse-phase C18 columns with mobile phase consisting of water-acetonitrile-phosphoric acid (90:10:0.1). Gas chromatography following derivatization with BSTFA (N,O-bis(trimethylsilyl)trifluoroacetamide) provides excellent separation from other dicarboxylic acids with detection limit 0.1 μg/mL. Titrimetric analysis with standardized sodium hydroxide solution using phenolphthalein indicator allows quantitative determination with relative error less than 0.5%.

Applications and Uses

Industrial and Commercial Applications

Nylon-6,6 production consumes approximately 60% of global adipic acid output, with polymerization occurring through polycondensation with hexamethylenediamine at 280-300 °C. The compound serves as plasticizer precursor through esterification with C8-C10 alcohols producing compounds such as dioctyl adipate and bis(2-ethylhexyl) adipate, which impart flexibility to polyvinyl chloride products. Polyurethane synthesis utilizes adipic acid in production of polyester polyols for flexible foam applications. Food industry applications employ adipic acid as acidulant (E355) in baking powders, gelatin desserts, and beverage formulations where it provides tartness without hygroscopicity. Pharmaceutical applications include use as excipient in controlled-release formulations where it modulates drug release profiles through pH adjustment.

Historical Development and Discovery

Auguste Laurent first documented adipic acid in 1837 during investigations of nitric acid oxidation products of various fats and oils. The compound initially attracted limited attention until the emergence of synthetic polymer chemistry during the early twentieth century. Wallace Carothers' systematic investigation of polycondensation reactions at DuPont during the 1930s revealed the exceptional suitability of adipic acid for nylon production. Industrial-scale production developed rapidly following the commercialization of nylon-6,6 in 1938. Manufacturing processes evolved from initial nitric acid oxidation of cyclohexanol to current catalytic methods utilizing air oxidation. Environmental concerns regarding nitrous oxide emissions from nitric acid-based processes have driven development of alternative synthetic routes including hydrocarbonylation of butadiene and biological production methods.

Conclusion

Adipic acid represents a paradigm of industrial organic chemistry, where fundamental molecular structure dictates widespread technological application. The six-carbon dicarboxylic acid structure provides optimal geometry for polycondensation reactions producing high-performance polyamides. Well-characterized physical properties including melting behavior, solubility characteristics, and crystalline structure facilitate industrial processing and purification. Chemical reactivity follows predictable patterns of carboxylic acid functionality while exhibiting unique transformations such as cyclopentanone formation under specific conditions. Ongoing research focuses on sustainable production methods addressing environmental concerns associated with traditional manufacturing processes. The compound continues to serve as foundational material for polymer science while finding expanding applications in materials chemistry and pharmaceutical technology.

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Przykłady: H2O, CO2, CH4, NH3, NaCl, CaCO3, H2SO4, C6H12O6, woda, dwutlenek węgla, metan, amoniak, chlorek sodu, węglan wapnia, kwas siarkowy, glukoza.

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