At infinite dilution, the equivalent conductivity of the electrolyte is
given by the expression:
`^^^_(eq)^(oo)=lambda_((+))^(oo)+lambda_((-))^(oo)`
The above expression is given by

The increase in equivalent conductivity of a weak electrolyte with dilution is due to :

The equivalent conductance of CH_3COOH at infinite dilution is given by

An increase in equivalent conductance of a strong electrolyte with dilution is mainly due to:

At infinite dilution of an electrolyte, the equivalent conductance of cations at anions are ………………… of each other.

State Kohlrausch law for electrical conductance of an electrolyte at infinite dilution.

Which of the following solution has the highes t equivalent conductance at infinite dilution ?

According of Kohlrausch law, the limiting value of molar conductivity of an electrolyte A_(2)B is (a) lambda^(oo) ._(A^(+)) + lambda^(oo) ._((B^(-)) (b) lambda^(oo) ._(A^(+)) - lambda^(oo) ._(B^(-)) (c) 2lambda^(oo) ._(A^(+)) +(1)/(2)lambda^(oo) ._((B^(-)) (d) 2lambda^(oo) ._(A^(+)) + lambda^(oo) ._(B^(-))

The equivalent conductance of NaCl at concentration C and at infinite dilution are lambda_(C) and lambda_(oo) , respectively. The correct relationship between lambda_(C) and lambda_(oo) is given as (where, the constant B is positive)

Which of the following expressions correctly repesents the equivalent conductance at infinte dilution of Al_(2)(SO_(4))_(3) . Given that Lambda_(Al^(3+))^(@) and Lambda_(SO_(4)^(2-))^(@) are the equivalent conductance at infinte dilution of the respective ions?

For 0.0128 N solution fo acetic at 25^(@)C equivalent conductance of the solution is 1.4 mho cm^(3) eq^(-1) and lambda^(oo) = 391 mho cm^(2)eq^(-1) . Calculate dissociation constant (K_(a)) of acetic acid.