The coexistence curves of {xC6H5NO2+ (1−x)CH3(CH2)10CH3} in the critical region

The coexistence curves of xC H NO H 6 5 2 ( ) ( ) } 1Ix CH CH CH and 3 2 3 3 { ( ) ( ) } x C H NO H 1 I x CH CH CH

Coexistence curves for {xC6H5NO2 + (1 -x)CH3(CH2)12CH3} have been determined by measurements of refractive index. The critical amplitude B and the critical exponent b have been deduced from (T, n), (T, x), and (T, f) curves, where n, x, and f are refractive index, mole fraction, and volume fraction,

The coexistence curves and the turbidity of nitrobenzene q octane have been measured and the critical amplitudes and exponents have been deduced. The values of exponents are consistent with theoretical predictions. The experimental results of coexistence curves have also been analysed to examine Weg

The coexistence curves and the turbidity of nitrobenzene q undecane have been measured, and the critical amplitudes and exponents relating to the difference of density variables of two coexisting phases, the correlation length, and the osmotic compressibility have been deduced. The values of exponen

Coexistence curves for 4x(CHCOOC2H5)2 + (1 -x)CH3(CH2)6CH35 have been determined by measurements of the refractive index. The critical amplitude B and the critical exponent b have been deduced from (T, n), (T, x), and (T, f) (where n, x, and f are refractive index, mole fraction, and volume fraction

Coexistence curves for x CHCOOC H q 1 y x CH CH CH have been determined 2 5 2 3 2 4 3 by measurement of refractive index. The critical amplitude B and the critical exponent ␤ Ž . Ž . Ž . Ž have been deduced from T, n , T, x , and T, where n, x, and are the refractive . index, the mole fraction, and