The equilvalnet conductances of NaCl at concentration C and at inifnite dilution are `lambda_c` and `lambda_infty` respectively. The correct rltionship between `lambda_c` and `lambda_infty` is given as

Calculate the molar conductance at infinite dilution (lambda^om) of CaCl_2 ,given that molar ionic conductance for lambda^om(Ca^(2+)) 119.5 and Cl- (76.3) S cm^2mol^(-1)

The following curve is obtained when molar conductivty, Lambda_m is plotted against the square rot of concentration, C^(1//2) along y and x axis respectively for the two electrolytes X and Y. How do you account for the increase in Lambda_m for the electolytes X and Y with dilution?

Calculate the molar conductance of a solution of MgCl_2 at infinite dilution, gievn that the molar ionic conductance of lambda^o (Mg^(2+))=126.1S cm^2mol^(-1) and lambda^o (Cl^(-))=56.3 Scm^2mol^(-1) .

You are given three solutions A,B and C. the pH values of the solutions are 4.5, 7.0 and 10.0 respectively? minimum concentration of H_3O^(+) ion?

10 different vectors are lying on a plane out of which four are parallel with respect to each other. Probability that three vectors chosen from them will satisfy the equation lambda_1a+lambda_2b+lambda_3c=0, where lambda_1, lambda_2 and lambda_3ne=0 is

The molar conductance of KCl solution at different concentrations at 298 K are given below: Plot a graph between wedge_(m) and c^(1//2) and determine the value of wedge_(m)^(@) from it.

The molar conductance of HCl solution at different concentration at 298 K are given below : Plot a graph between wedge_(m) and c^(1//2) and determine the value of wedge_(m)^(@) from it.

If a, b and c are non-coplanar vectors and d=lambda vec a+mu vec b+nu vec c , then lambda is equal to