Given the two concentration of HCN `(K_(a)=10^(-9))` are `0.1` M and `0.001` M respectively. What will be the ratio of degree of dissociation?

The equivalent conductivites of acetic acid at 298K at the concentration of 0.1M and 0.001M are 5.20 and 49.2S cm^(2) eq^(-1) respectively. Calculate the degree of dissociation of acetic acid at the these concentrations. Given that, lambda^(prop) (H^(+)) and lambda^(prop) (CH_(3)COO^(-)) are 349.8 and 40.9 ohm^(-1) cm^(2) mol^(-1) respectively.

The equilibrium constant K_(p_(1)) and K_(p_(2)) for the reactions XhArr2Y and ZhArrP+Q , respectively are in the ratio of 1:9 . If the degree of dissociation of X and Z be equal, then the ratio of total pressure at these equilibrium is:

We have three aqueous solutions of NaCl labelled as A, B and C with concentration 0.1 M , 0.01 "and" 0.001 M , respectively . The value of van't Hoff factor for these solutions will be in the order :

We have three aqueous solutions of NaCl labelled as A, B and C with concentration 0.1 M , 0.01 "and" 0.001 M , respectively . The value of van't Hoff factor for these solutions will be in the order :

The ionization constant of phenol is 1.0xx10^(-10) . What is the concentration of phenolate ion in 0.05 M solution of phenol? What will be its degree of ionization if the solution is also 0.01 M in sodium phenolate?

HA is a weak acid. The pH of 0.1 M HA solution is 2. What is the degree of dissociation (alpha) of HA ?

Four solution of NH_(4)Cl are taken with concentration 1M,0.1M,0.01M & 0.001M . Their degree of hydrolysis are h_(1),h_(2) & h_(3),h_(4) . What is the gradation of degree of hydrolysis

The acid dissociation constant of uric acid is K_(a)=4.0xx10^(-6) M. The pH of a sample of urine is 6.0. What is the ratio of concentration of urate ion to uric acid in the urine? (a) 2.0 (b) 4.0 (c) 6.0 (d) 0.25

K_(1) & K_(2) for oxalic acid are 6.5 xx 10^(-2) and 6.1 xx 10^(-5) respectively . What will be the [OH^(-)] in a 0.01 M solution of sodium oxalate

The degree of dissociation of 0.1N CH_(3)COOH is (K_(a)= 1xx10^(-5))