[" 3) Both (a) and (b) "],[" According to Konirausch law,the limiting value "],[" of molar conductivity of an electrolyte "A_(2)B" is "],[" 2) "lambda^(2)x-lambda^(2)m^(2)]

According to Kohlrausch law, the limiting value of molar conductivity of an electrolyte A_2B is

According of Kohlrausch law, the limiting value of molar conductivity of an electrolyte A_(2)B is

According to Kohlrausch law, the limiting, value of molar conductivity of an eletrolyte, A_2B is

According to Kohlrausch law, the limitiing value of molar conductiviity of a electrolyte A_2B is

According to Kohlrausch law, the limiting molar conductivity of an electrolyte, A_(m)B_(n) , can be expressed as

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^(-))

Assertion : If lambda_(Na)A^(@) + lambda_(CI^(-))^(@) are molar limiting conductivity of the sodium and chloride ions respectively, then the limiting molar conducting for sodium chloride is given by the equation: lambda_(NaCI)^(@)=lambda_(Na)^(@)+lambda_(Cl^(-))^(@) Reason : This is according to Kohlrausch's law of independent migration of ions.