`Lambda_(ClCH_(2)COONa)^(@)=224 Ohm^(-1)cm^(2)g meq^(-1), Lambda_(NaCl)^(@)=38.2Ohm^(-1)cm^(2)gm eq^(-1), Lambda_( HCl)^(@)=203Ohm^(-1)cm^(2)gm eq^(-1)`. What is the value of `L_(ClCH_(2)COOH)^(@)` ?

Lambda_(c) of acetic acid at 25^(@)C is 16.3 ohm^(-1)cm^(2)eq^(-1) . The ionic conductances of H^(+) and CH_(3)COO^(-) are 349.83 and 40.89 ohm^(-1) . What is prop of CH_(3)COOH ?

lambda_(HCN) is 0.1 M solution is 20S m^(2) " mol"^(-1) lambda_(HCN)^(@) is 200S m^(2) "mol"^(-1) . The P^(H) of 0.1M HCN solution is ____________

If the values of wedge_(infty) of NH_(4)Cl, NaOH and NaCl are 130, 217 and 109 ohm^(-1) cm^(2) equiv^(-1) respectively, the wedge_(infty) of NH_(4)OH in ohm^(-1) cm^(2) equiv^(-1) is

The equivalent conductances of two strong electrolytes at infinite dilutution in H_2O ( where ion move freely through a solution ) at 25^(@)C are give below Lambda_(CH_3COONa)^(0) = 91.0 S cm^(2)//"equiv", Lambda_(HCl)^(0) = 426.2 S cm^(2)//"equiv" What additional information / quantity one needs to calculate Lambda^(0) of an aqueous solution of acetic acid ?

If bc+ca+ab=18 , and |(1,a^(2),a^(3)),(1,b^(2),b^(3)),(1,c^(2),c^(3))|=lambda|(1,1,1),(a,b,c),(a^(2),b^(2),c^(2))| the value of lambda is

At 25^@C equivalent conductance of a week acid HAc is 16.2 "ohm"^(-1) cm^(2) eq^(-1) .If the ionic conductances of Ac^(-) and H^(+) at infinite dilution are respectively 40.9 and 349.8 "ohm"^(-1)cm^(2)eq^(-1)., calculate the percentage dissociation of the week acid at 25^@C .

If (1)/(n+1)+(1)/(2(n+1)^(2))+(1)/(3(n+1)^(3))+….= lambda((1)/(n)-(1)/(2n^(2))+(1)/(3n^(3))-……) then lambda=