[" lonic conductance of "H^(*)" and "SO_(4)-" are "x" and "yScm^(2)" mort.Hen "],[[" (1) "2x+(y)/(2)," D) "x+y]]

Ionic conductance of H^(+) and SO_(4) are x and yS cm^(2) mol^(-1) . Hence equivalent conductivity of H_(2)SO_(4) is

Ionic conductance of H^(+) and SO_(4) are x and yS cm^(2) mol^(-1) . Hence equivalent conductivity of H_(2)SO_(4) is

Ionic conductance of H^(+) and SO_(4)""( 2–) at infinite dilution are x and y S "cm"^(2)" equiv "^(–1) . Hence, equivalent conductance of H_(2) SO_(4) at inifinite dilution will be:

Ionic conductances of H^(+) and SO_(4)^(2-) at infinite dilution are x and y S cm^(2) "equiv"^(-1) . Hence, equivalent conductance of H_(2)SO_(4) at infinite dilution is:

The ionic conductance of H^(+) and SO_(4)^(2-) are 350 and 80 S cm^(2) "equiv"^(-1) hence equivalent conductance S cms^(2) "equivalent"^(-1) and molar conductance S cm^(2)"mol"^(-1) of H_(2)SO_(4) will be

The ionic equivalent conductivities of K^(o+), Al^(3+) , and SO_(4)^(2-) ions are x,y, and z S cm^(2) Eq^(-1) , respectively. Calculate wedge_(m)^(@) and wedge_(eq)^(@) for (K_(2)SO_(4).Al_(2)(SO_(4))_(3).24H_(2)O)( Potash alum ).

The ionic equivalent conductivities of K^(o+), Al^(3+) , and SO_(4)^(2-) ions are x,y, and z S cm^(2) Eq^(-1) , respectively. Calculate wedge_(m)^(@) and wedge_(eq)^(@) for (K_(2)SO_(4).Al_(2)(SO_(4))_(3).24H_(2)O)( Potash alum ).

The ionic equivalent conductivities of K^(o+), Al^(3+) , and SO_(4)^(2-) ions are x,y, and z S cm^(2) Eq^(-1) , respectively. Calculate wedge_(m)^(@) and wedge_(eq)^(@) for (K_(2)SO_(4).Al_(2)(SO_(4))_(3).24H_(2)O)( Potash alum ).