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

Lambda_(m(H_(2)O)^(@) is equal to -

Calculating the value of Lambda_(m)^(@) for NH_(4)OH solution requires the value of Lambda_(m)^(@) for the solutions of NH_(4)Cl, NaOH and an electrolyte. Name the electrolyte.

For which one of the following electrolyte solutions can we apply Kohlrausch's law to determine Lambda_(m)^(@) of the solution ? CH_(3)COONa, HCOOH, NH_(4)Cl.

Lambda_(m)^(@) of NaCl, HCl and CH_(3)COONa are 126.4, 425.9 and "91.0 S.cm"^(2)."mol"^(-1) respectively. Lambda_(m)^(@) for CH_(3)COOH will be -

The values of Lambda_(m)^(@) for the aqueous solution of KCl and KNO_(3) are 149.86ohm^(-1)"cm"^(2)mol^(-1) and 145 ohm^(-1)cm^(2)mol^(-1) , respectively. If lambda_(m)^(@)(Cl^(-)) is "76.44 ohm"^(-1)."cm"^(2)."mol"^(-1) then lambda_(m)^(@)(NO_3^(-)) will be?

Lambda_(m)^(@) for NaCl, HCl and NaAc are 126.4, 425.9 and "91 S.cm"^(2)."mol"^(-1) respectively. Calculate Lambda^(@) for Hac.

O P Q R is a square and M ,N are the midpoints of the sides P Q and Q R , respectively. If the ratio of the area of the square to that of triangle O M N is lambda:6, then lambda/4 is equal to 2 (b) 4 (c) 2 (d) 16

BH_(4)^(-) and NH_(4)^(-) ions are isolobal - explain.

At infinite dilution, Lambda_(m)^(@) for K_(2)SO_(4) solution is x "ohm"^(-1)."cm"^(2)."mol"^(-1) , and ionic conductance (lambda^(@)) for SO_(4)^(2-) is "y ohm"^(-1)."cm"^(2)."mol"^(-1) . Find the value of lambda^(@) for K^(+) ion.

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?