If `Lambda_(m)^(*)` for `Ba(OH)_(2) BaCl_(2)` and` NH_(4)Cl` are x y and z respectively then `Lambda_(m)^(*)` of `NH_(4)OH` is

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

Calculate lamda_(m)^(@) for NH_(4)OH given that values of lamda_(m)^(@) for Ba(OH)_(2), BaCl_(2) and NH_(4)Cl as 523.28, 280.0 and 129.8 S cm^(2) mol^(-1) respectively.

Calculate lambda_(m)^(@) for NH_(4)OH given that values of lambda_(m)^(@) for Ba(OH)_(2) BaCI_(2) and NH_(4)CI as 523.28 280.0and 129.8 S cm^(2) mol^(-1) respectively

At 298 K the molar conductivities at infinite dilution (^^_(m)^(@)) of NH_(4)Cl, KOH and KCl are 152.8, 272.6 and "149.8 S cm"^(2)"mol"^(-1) respectively. The ^^_(m)^(@) of NH_(4)OH in "S cm"^(2)"mol"^(-1) and % dissociation of 0.01 M NH_(4)OH with ^^_(m)="25.1 S cm"^(2)"mol"^(-1) at the same temperature are

Calculate molar conductance for NH_(4)OH , given that molar conductance for Ba(OH)_(2), BaCl_(2) and NH_(4)Cl are 523.28, 280.0 and 129.8 ohm^(-1) cm^(2) mol^(-1) respectively.

(NH_(4))_(2)SO_(4)+Ba(OH)_(2) to BaSO_(4)darr+2NH_(3)uarr

(NH_(4))_(2)SO_(4)+Ba(OH)_(2) to BaSO_(4)darr+2NH_(3)uarr

Hg_2Cl_2 + NH_4OH to

Al_(2)(SO_(4))_(3) + NH_(4)OH rarr X , X is.

Limiting molar conductivity of NH_(4)OH [i.e., Lambda_(m)^(@)(NH_(4)OH) ] is equal to: