The equivalent conductance of an infinitely dilute solution of `Al_(2)(SO_(4))_(3)` is `Lambda^(@)`. What is the value of `Lambda_(m)^(@)` for the solution?

The van't Hoff factor i for an infinitely dilute solution of NaHSO_4 is

The order of equivalent conductance at infinite dilution for LiCl, NaCl and KCl is -

What is molar conductivity at infinite dilution?

If the equivalent ionic conductances of Al^(3+) and SO_(4)^(2-) ions are lambda_(Al^(3+))^(@) and lambda_(SO_(4)^(2-))^(@) , respectively, in an infinitely dilute solution of Al_(2)(SO_(4))_(3) , then the equivalent conductance of the solution would be -

What is the equivalent weight of KMnO_(4) in acidic solution?

The molar ionic conductances of Al(3+) and SO_(5)^(2-) ions in an infinitely dilute solution of Al_(2)(SO_(4))_(3) are 189 and "160 ohm"^(-1)."cm"^(2)."mol"^(-1), respectively. Determine Lambda^(@) and Lambda_(m)^(@) of Al_(2)(SO_(4))_(3) solution.

At a definite temperature, the molar conductivity of a weak electrolytic solution of concentration, C(M) is Lambda_(m) and the value of the molar conductivity at infinite dilution of the same electrolysis solution is Lambda_(m)^(@) . What will be the value of degree of dissociation of the electrolytr C(M) solution?

NaOH solution is added to Al_2(SO_4)_3) solution?

Lambda_(m(NH_(4)OH)^(@) is equal to -

The electrolyte A_(2)B dissociates in aqueous solution as A_(2)B(aq)rarr 2A^(+)(aq)+B^(2-)(aq) . If molar ionic conductance at infinite dilution of A^(+) and B^(2-) ions are lambda_(m)^(@)(A^(+)) and lambda_(m)^(@)(B^(2-)) respectively when what will be the value of Lambda_(m)^(@) of A_(2)B ?