For a `0.01 M CH_(2)COOH` solution, `wedge_(m)=7.8 Omega^(-1)cm^(2) mol^(-1)` if `wedge_(m)^(@)=390Omega^(-1)cm^(2)mol^(-1)` . What is the degree of the dissociation `(alpha)` of acetic acid ?

For a 0.01 M CH_(3)COOH solution, wedge_(m)=7.8 Omega^(-1)cm^(2) mol^(-1) if wedge_(m)^(@)=390Omega^(-1)cm^(2)mol^(-1) . What is the degree of the dissociation (alpha) of acetic acid ?

The molar conductivity of 0.05 M solution of weak acid is 16.6Omega^(-1)cm^(-2)mol^(-1). Its molar conductivity at infinite dilution is 390.7Omega^(-1)cm^(-2)mol^(-1) . The degree of dissociation of weak acid is

The molar conductivity of 0.05 M solution of weak acid is 16.6Omega^(-1)cm^(-2)mol^(-1). Its molar conductivity at infinite dilution is 390.7Omega^(-1)cm^(-2)mol^(-1) . The degree of dissociation of weak acid is

A conductivity cell whose cell constant is 3.0 cm^(-1) is filled with 0.1 M solution of a weak acid. Its resistance is found to be 3000 Omega . If wedge_(m)^(infty)= 400 Omega^(-1) cm^(2) mol^(-1) , the degree of dissociation of the weak acid is about

From the following molar conductivities at infinite dilution : wedge_(m)^(@) for Ba(OH)_(2)=457.6Omega^(1)cm^(2)mol^(-1) wedge_(m)^(@) for BaCl_(2)=240.6Omega^(-1) cm^(2)mol^(-1) wedge_(m)^(@) for NH_(4)Cl=129.8 Omega^(-1) cm^(2) mol^(-1) Calculate wedge_(m)^(@) for NH_(4)OH .

From the following molar conductivities at infinite dilution : wedge_(m)^(@) for Ba(OH)_(2)=457.6Omega^(1)cm^(2)mol^(-1) wedge_(m)^(@) for BaCl_(2)=240.6Omega^(-1) cm^(2)mol^(-1) wedge_(m)^(@) for NH_(4)Cl=129.8 Omega^(-1) cm^(2) mol^(-1) Calculate wedge_(m)^(@) for NH_(4)OH .

From the following molar conductivities at infinite dilution : wedge_(m)^(@) for Ba(OH)_(2)=457.6Omega^(1)cm^(2)mol^(-1) wedge_(m)^(@) for BaCl_(2)=240.6Omega^(-1) cm^(2)mol^(-1) wedge_(m)^(@) for NH_(4)Cl=129.8 Omega^(-1) cm^(2) mol^(-1) Calculate wedge_(m)^(@) for NH_(4)OH .