ABSTRACT

Densities and speeds of sound were measured for six binary mixtures of water + room temperature ionic liquids (RTILs) of type [Cnpy][X] or [Cn4mpy][X] (where n = 6 or 8, [X] = Cl or Br ) at T = (308.15 and 318.15) K at atmospheric pressure. The molar excess volumes (VmE) excess speeds of sound (E), and excess isentropic compressibilities (sE) were calculated from the experimental data. Addition of a small amount of RTIL drastically increased the densities of water initially. The VmE values for water + chloride-based RTILs were more negative across the composition compared to the mixtures with bromide-based RTILs; the negative magnitudes, however, decreased as the alkyl chain length and temperature increased. Speeds of sound of the mixtures could be adequately predicted by the collision factor theory and Nomoto equation. The E values were positive, while sE values were negative across the composition. The negative VmE and sE values in general suggest the predominance of strong heterointeractions, which become enhanced with the increase in hydrocarbon chain length. Analysis of partial excess molar volumes or isentropic compressibilities and their standard transfer functions revealed that, compared to those of the Cl anion, the Br anion has the weakest water***RTIL interactions.

Compounds

#	Formula	Name
1	C11H18ClN	1-hexylpyridinium chloride
2	C13H22ClN	N-octylpyridinium chloride
3	C11H18BrN	1-hexylpyridinium bromide
4	C13H22BrN	1-octylpyridinium bromide
5	C12H20BrN	1-hexyl-4-methylpyridinium bromide
6	H2O	water
7	C14H24ClN	4-methyl-1-octylpyridinium chloride

Datasets

The table above is generated from the ThermoML associated json file (link above). POMD and RXND refer to PureOrMixture and Reaction Datasets. The compound numbers are included in properties, variables, and phases, if specificied; the numbers refer to the table of compounds on the left.
Type	Compound-#	Property	Variable	Constraint	Phase	Method	#Points
POMD	1	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	1	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	2	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	2	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	3	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	3	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	4	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	4	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	5	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	5	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	6	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	6	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	7	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	2
POMD	7	Speed of sound, m/s ; Liquid	Temperature, K; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	2
POMD	1 6	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	32
POMD	1 6	Speed of sound, m/s ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	32
POMD	2 6	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	32
POMD	2 6	Speed of sound, m/s ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	32
POMD	6 3	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	32
POMD	6 3	Speed of sound, m/s ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	32
POMD	4 6	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	32
POMD	4 6	Speed of sound, m/s ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	32
POMD	6 5	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	32
POMD	6 5	Speed of sound, m/s ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	32
POMD	6 7	Mass density, kg/m3 ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Vibrating tube method	32
POMD	6 7	Speed of sound, m/s ; Liquid	Temperature, K; Liquid Mole fraction - 6; Liquid	Pressure, kPa; Liquid	Liquid	Sing-around technique in a fixed-path interferometer	32

Thermodynamics Research Center / ThermoML | Journal of Chemical and Engineering Data

Densities, Speeds of Sound, and Excess and Partial Excess Properties of Room Temperature Ionic Liquids of Type [Cnpy][X] or [Cn4mpy][X] (Where n = 6 or 8, [X] = Cl or Br ) + Water Binary Mixtures at T = (308.15 and 318.15) K

Sastry, N. V.[Nandhibatla V], Ravalji, I. R.[Indravijaysinh R]

ABSTRACT