Relationship between structure and biodegradability of gemini imidazolium surface active ionic liquids

Three ester-containing gemini imidazolium surface active ionic liquids [1,4-bis(1-alkyl-oxypropyl-imidazolium)-butane dichloride], abbreviated as [peC _n Bim ₂ ]Cl ₂ (n = 12, 14, 16), were synthesized from imidazole, 1,4-dibromobutane, 1-chloro-3-propanol, and various aliphatic carboxylic acids. Chemical structures of [peC _n Bim ₂ ]Cl ₂ were confirmed by H-Nuclear magnetic resonance, Fourier transform infrared spectroscopy, and elemental analysis. Thermal properties of [peC _n Bim ₂ ]Cl ₂ were studied with Thermogravimetric analysis and Differential scanning calorimetry. The micellization parameters, adsorption/aggregation properties, and thermodynamic parameters of [peC _n Bim ₂ ]Cl ₂ were demonstrated using tensiometry, electrical conductivity. Critical micelle concentration values of [peC _n Bim ₂ ]Cl ₂ aqueous solutions decreased with increasing the alkyl chain length (from C12 to C16). The formation of micelles was spontaneous, exothermic, and entropy-driven. Using OECD 301D, the aerobic biodegradation of nine gemini imidazolium SAILs ([peC _n Bim ₂ ]Cl ₂ , [C _n Pim ₂ ]Br ₂ , and [C _n Bim ₂ ]Br ₂ ) and three monoimidazolium SAILs ([C _n IM]Br) were systematically investigated to determine the relationship between biodegradation and structural elements of imidazolium SAILs. Aerobic biodegradation of twelve SAILs followed the decreasing trend: [peC _n Bim ₂ ]Cl ₂ > [C _n Pim ₂ ]Br ₂ > [C _n IM]Br > [C _n Bim ₂ ]Br ₂ . Gemini imidazolium SAILs with ester functional group ([C _n Pim ₂ ]Br ₂ and [peC _n Bim ₂ ]Cl ₂ ) showed much higher biodegradation rates than those of [C _n IM]Br and [C _n Bim ₂ ]Br ₂ . The location of ester group played an obvious role on biodegradation. Gemini SAILs containing ester group in the side alkyl chains ([peC _n Bim ₂ ]Cl ₂ ) showed much higher biodegradation ratio than those of [C _n Pim ₂ ]Br ₂ (ester functional group in spacer). [peC _n Bim ₂ ]Cl ₂ could be classified as readily biodegradable. The biodegradability of gemini imidazolium SAILs increased with increasing the alkyl chain length.