Molar conductances of `BaCl_(2), H_(2)SO_(4)` and HCl at infinite dilution are and `X_(1),X_(2)`, and `X_(3)` respectively. Molar conductance of `BaSO_(4)` at infinte dilution is

The molar conductance at infinite dilution of AgNO_(3), NaCl and NaNO_(3) are 116.5, 110.3 and 105.2 ohm^(-1)cm^(2)"mole"^(-1) respectively. The molar conductance of at infinite dilution is

The molar conductivities of H^(+) and HCOO^(-) ions at infinite dilution are 34.7 and 5.4 mSm^(2) " mol"^(-1) respectively. The molar conductivity of 0.25 M HCOOH is 4.0 mSm^(2) mol^(-1) . Then pK_(a) of formic acid is

The equivalent conductance at infinite dilution of NaCl, HCl and CH_3 COONa at 298K are 126.0, 426.0 and 91.0 ohm^(-1)cm^(2) respectively. The value of equivalent conductance of acetic acid at infinite dilution at the same temperature is

At infinite dilution molar conductivity of Ba^(2+) and Cl^(-) ions are =127.32S cm^(2)//mol and 76.34S cm^(2)//mol respectively. What is Lambda_(m)^(oo) for BaCl_(2) at same dilution?

The molar conductivities Lambda_(NaOAc)^(0) and Lambda_(HCl)^(0) at infinite dilute in water at 25^(@) C are 91.0 S cm^(2)//"mol" and 426.2 S cm^(2)//"mol" respectively . To calculate Lambda_(HOAc)^(0) the additional value required 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 .

Equal volumes of equi molar HCl and H_(2)SO_(4) are separately neutralised by dilute NaOH solution, then heats liberated and x kCal and y kCal respectively. Which of the following is true.

Conductors allow the passage of electric current through them. Metallic and electrolytic are the two types of conductors. Current carriers in metallic and electrolytic conductors are free electrons and free ions respectively. Specific conductance or conductivity of the electrolyte solution is given by the following relation: K= cx (l)/(A) where, c=1/R is the conductance and 1/A is the cell constant, Molar conductance (^^_m) and equivalence conductance (^^_e) of an electrolyte solution are calculated using the following similar relations: ^^_m = K xx (1000)/(M) ^^_(e) = K xx (1000)/(N) where, M and N are the molarity and normality of the solution respectively. Molar conductance of strong electrolyte depends on concentration : ^^_m = ^^_m^(0) - b sqrt(C) ^^_m^(0) = molar conductance at infinite dilution C = concentration of the solution b = constant The degrees of dissociation of weak electrolytes are calculated as alpha = (^^_m)/(^^_m^(0)) = (^^_e)/(^^_e^(0)) Which of the following decreases on dilution of electrolytic solution?