The equivalent conductance of NaCl at concentration C and at infinite dilution are `lambda_(C )` and `lambda_(oo)`, respectively . The correct relationship between `lambda_(C)` and `lambda_(oo)`is given as:
(where the constant B is positive).

The molar conductance of NaCl varies with the concentration as shown in the following table and all values follows the equation lambda_m^( C)=lambda_m^(oo)-bsqrtC where lambda_(m)^( C) =molar specific conductance lambda_(m)^(oo) =molar specific conductance at infinite dilution C=molar concentration {:("Molar Concentration of NaCl","Molar Conductance" "In" "ohm"^(-1)cm^(2)"mole"^(-1)),(4xx10^(-4),107),(9xx10^(-4),97),(16xx10^(-4),87):} When a certain conductivity cell (C) was filled with 25xx10^(-4) (M) NaCl solution.The resistance of the cell was found to be 1000 ohm.At Infinite dilution, conductance of Cl^(-) and SO_4^(-2) are 80 ohm^(-1) cm^(2) "mole"^(-1) and 160 ohm^(-1) cm^2 "mole"^(-1) respectively. If the cell ( C) is filled with 5xx10^(-3)(N)Na_(2)SO_(4) the obserbed resistance was 400 ohm.What is the molar conductance of Na_(2)SO_(4) .

In the figure shown a sinusoidal wave is generated at the end 'A' . The wave travels along positive x- axis and during its motions it encounter another string BC at the junction 'B' at x = 0 . The density of strings AB and BC and rho and 9rho respectively and their radii of cross sections are 2r and r . The wave funcation. amplitude and wavelength of incident wavs are respectively y_(r), A_(r), lambda_(r) and y_(t), A_(t), lambda_(t) repectively The ratio of wavelengths lambda_(r) to lambda_(t) (i.e. lambda_(r) : lambda_(t) ) will be

The molar conductance of NaCl varies with the concentration as shown in the following table and all values follows the equation. lambda_(m)^(c)=lambda_(m)^(oo)-bsqrt(C) where lambda_(m)^(c) = molar specific conductance lambda_(m)^(oo)= molar specific conductance at infinite dilution C=molar concentration When a certain conductivity cell (C) was filled with 25 xx10^(-4)(M) NaCl solution, the resistance of the cell was found to be 1000 ohm. At infinite dilution, conductance of Cl^(-) and SO_(4)^(2-) are 80ohm^(-1) cm^(2) "mole"^(-1) and 160ohm^(-1) cm^(2) "mole"^(-1) respectively. What is the molar conductance of NaCl at infinite dilution?

The molar conductance of NaCl varies with the concentration as shown in the following table and all values follows the equation. lambda_(m)^(c)=lambda_(m)^(oo)-bsqrt(C) where lambda_(m)^(c) = molar specific conductance lambda_(m)^(oo)= molar specific conductance at infinite dilution C=molar concentration When a certain conductivity cell (C) was filled with 25 xx10^(-4)(M) NaCl solution, the resistance of the cell was found to be 1000 ohm. At infinite dilution, conductance of Cl^(-) and SO_(4)^(2-) are 80ohm^(-1) cm^(2) "mole"^(-1) and 160ohm^(-1) cm^(2) "mole"^(-1) respectively. What is the cell constant of the conductivity cell (C)?

Calculate the equivalent conductance of NH_4OH at infinite dilution using Kohlrausch law. Given that Lambda_(0) values of NaOH, NaCI and NH_4Cl are respectively 217.4, 108.9 and 129"ohm"^(-1) cm^(2) .

At infinite dilution, the equivalent conductivity of the electrolyte is given by the expression: ^^^_(eq)^(oo)=lambda_((+))^(oo)+lambda_((-))^(oo) The above expression is given by

The molar conductivities Lambda_(NaOAc)^@ and Lambda_(HCI)^@ at infinite dilution is watter at 25^@C are 91.0 and 426.2 S cm^@ // mol respectively. To calculate Lambda_(HOAc,)^2 the additional value required is:

The molar conductivity of NaCl, CH_(3)COONa and HCl at infinite dilution is 126.45, 91.0 and 426.16 "ohm"^(-1) "cm"^(2) "mol"^(-1) respectively. Calculate the molar conductivity (lambda_(m)^(oo)) for CH_(3)COOH at infinite dilution.

Two particles A and B of de-broglie wavelength lambda_(1) and lambda_(2) combine to from a particle C. The process conserves momentum. Find the de-Broglie wavelength of the particle C. (The motion is one dimensional).

Two particles A and B of de-broglie wavelength lambda_(1) and lambda_(2) combine to from a particle C. The process conserves momentum. Find the de-Broglie wavelength of the particle C. (The motion is one dimensional).