Calculate `(A_(HOAC)^(@))` using appropriate molar conductances of the electrolytes listed above at infinite dilution in ` H_(2)O` at `25^(@)C` .

{:("Electrolyte",^^.^(oo)(Scm^(2)mol^(-1))),(KCl,149.9),(KNO_(3),145.0),(HCl,426.2),(NaOAc,91.0),(NaCl,126.5):} Calculate ^^_(HOAc)^(oo) using appropriate molar conductance of the electrolytes listed above at infinite dilution in H_(2)O at 25^(@)C

Calculate, molar conductance of acetic acid using appropriate molar conductances of the electrolytes listed above at infinite dilution in H_(2)O at 25^(@)C :

The ionization constant of a weak electrolyte is 25 xx 10^(-6) while the equivalent conductance of its 0.01 M solution is 19.6 s cm^(2) eq^(-1) . The equivalent conductance of the electrolyte at infinite dilution (in S cm^(2)eq^(-1) ) will be

The specific conductance of a0.5 N solution of an electrolyte at 25^@C is 0.00045 Scm^(-1) . The equivalent conductance of this electrolyte at infinite dilution is 300 S cm^2eq^(-1) . The degree of dissociation of the electrolyte is

The equivalent conductances of two strong electrolytes at infinite dilution in H2O (where ions move freely through a solution) at 25^(@)C are given below: wedge_(CH_(3)COONa^(@) = 91.0Scm^(2)//equ iv , wedge_HCl^(@)= 426.25cm^(2)//equiv What additional information/quantity one needs to calculate overset(o)(wedge) of an aqueous solution of acetic acid?

Assertion:Kohlrausch law helps to find the molar conductivity of weak electrolyte at infinite dilution. Reason:Molar conductivity of a weak electrolyte at infinite dilution cannot be determined experimentally.

The ionization constant of a weak electrolyte is 2.5 xx 10^(-5) , while of the equivalent conductance of its 0.1 M solution is 19.6 s cm^(2) eq^(-1) . The equivalent conductance of the electrolyte at infinite dilution is :

The following curve is obtained when molar conductivity (wedge_(m)) is plotted against the square root of concentration, c^(1//2) for two electrolytes A and B (a) How do you account for the increase in the molar conductivity of the electrolyte A on dilution. (b) As seen from the graph, the value of limiting molar conductivity (wedge_(m)^(0)) for electrolyte B cannot be obtained graphically. How can this value be obtained?1

Specific conductance of pure water at 25^(@)C is 0.58 xx 10^(-7) mho cm^(-1) . Calculate ionic product of wter (K_(w)) if ionic conductances of H^(+) and OH^(-) ions at infinite are 350 and 198 mho cm^(2) respectively at 25^(@)C

Statement-I: Molar conductivity of a weak electrolyte at infinite dilution cannot be determined experimenttally. Because Statement-II: Kohlrausch law help to find the moar conductivity of a weak electrolyte at infinite dilution.