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

Degree of dissociation of 0.1 N CH_(3)COOH is ( Dissociation constant =1xx 10^(-5))

Which of the following solutions added to 1L of a 0.01 M CH_(3)COOH solution will cause no change in the degree of dissociation of CH_(3)COOH and pH of the solution ? (K_(a)=1.6xx10^(-5) for CH_(3)COOH)

The dissociation constant of 0.01 M CH_(3)COOH is 1.2xx10^(-5) then calculate the dissociation constant of its conjugate baze (CH_(3)COO^(-))

The dissociation constatn of 0.01 M CH_(3)COOH is 1.8xx10^(-5) then calculate CH_(3)COO^(-) concentration of 0.1 M HCl solution.

The equivalent conductivity of N/10 solution of acitic acid at 25^(@)C is 14.3 ohm^(-1) cm^(2) eq^(-1) . Calculate the degree of dissociation of CH_(3)COOH if Lambda_(oo CH_(3)COOH) is 390.71.

Calculate pH solution: 0.1 M CH_(3)COOH (K_a=1.8 xx 10^(-5))

Calculate pH solution: 10^(-8)M CH_(3)COOH (K_(a)=1.8 xx 10^(-5))

The degree of dissociation of weak electrolyde is inversely proportional to the square root fo concentration. It is called Ostwald's dilution law. alpha = sqrt((K_(a))/(c)) As the tempertaure increases, degree of dissociation will increase. (alpha_(1))/(alpha_(2)) = sqrt((K_(a_(1)))/(K_(a_(2)))) if concentration is same. (alpha_(1))/(alpha_(2)) = sqrt((c_(2))/(c_(1))) if acid is same. 0.01M CH_(3)COOH has 4.24% degree of dissociation, the degree of dissociation of 0.1M CH_(3)COOH will be