A dilute solution NaCI was placed between two Pt electrodes 8 cm apart across which a potential of 4V was appied how far would the `Na^(+)` move in 2.5 hour? Ionic conductance of `Na^(+)` at infinit e dikution at `25^(@)C` is 50.11 mho `cm^(2)`

A dilute aqueous solution of KCI was placed between two electrodes 10 cm apart, across which a potential of 6 volt was applied. How far would the K^(+) ion move in 2 hours at 25^(@)C ? Ionic conductance of K^(+) ion at infinite dilution at 25^(@)C is 73.52 ohm^(-1) cm^(2) "mole"^(-1) ?

A dilute solution of KCl was placed between two Pt electrodes 10cm apart across which a potential difference of 10 volt was applied. Which is /are correct statement (Given: molar conductivity of K^+ at infinite dilution is 96.5 Scm^2mol^(-1)

0.5N solution of a salt placed between two Pt electrodes 2.0 cm apart and having area of cross-section 2.5 cm^(2) has resistance of 25 ohms. Calculate the conductance and cell constant.

The resistance of decinormal solution of a salt occupying a volume between two platinum electrodes 1.80 cm apart and 5.4 cm^(2) area was found to be 32 ohm . Calculate k and wedge _(eq) .

The conductance of 0.0015 M aqueous solution of a weak monobasic acid was determined by using a conductivity cell consisting of platinized Pt electrodes. The distance between the electrodes is 120 cm with an area of cross-section of 1 cm^(2) . The conductance of this solution was found to be 5xx10^(-7) S . The pH of the solution is 4. Calculate the value of limiting molar conductivity.

A sample of water from a large swimming pool has a resistance of 10000Omega at 25^(@)C when placed in a certain conductace cell. When filled with 0.02M KCI solution, the cell has a resistance of 100 Omega at 25^(@)C, 585 gm of NaCI were dissolved in the pool, which was throughly stirred. A sample of this solution gave a resistance of 8000 Omega . Given: Molar conductance of NaCI at that concentration is 125 Omega^(-1) cm^(2) mol^(-1) and molar conductivity of KCI at 0.02 M is 200W^(-1) cm^(2) mol^(-1) . Conductivity (Scm^(-1)) of H_(2)O is:

A sample of water from a large swimming pool has a resistance of 10000Omega at 25^(@)C when placed in a certain conductace cell. When filled with 0.02M KCI solution, the cell has a resistance of 100 Omega at 25^(@)C, 585 gm of NaCI were dissolved in the pool, which was throughly stirred. A sample of this solution gave a resistance of 8000 Omega . Given: Molar conductance of NaCI at that concentration is 125 Omega^(-1) cm^(2) mol^(-1) and molar conductivity of KCI at 0.02 M is 200W^(-1) cm^(2) mol^(-1) . Cell constant (in cm^(-1)) of conductane cell is:

A sample of water from a large swimming pool has a resistance of 10000Omega at 25^(@)C when placed in a certain conductace cell. When filled with 0.02M KCI solution, the cell has a resistance of 100 Omega at 25^(@)C, 585 gm of NaCI were dissolved in the pool, which was throughly stirred. A sample of this solution gave a resistance of 8000 Omega . Given: Molar conductance of NaCI at that concentration is 125 Omega^(-1) cm^(2) mol^(-1) and molar conductivity of KCI at 0.02 M is 200W^(-1) cm^(2) mol^(-1) . Volume (in Litres) of water in the pool is:

Two parallel plate capacitors A and B have the same separation d=8.85xx10^-4m between the plates. The plate area of A and B are 0.04m^2 and 0.02m^2 respectively. A slab of dielectric constant (relative permittivity) K=9 has dimensions such that it can exactly fill the space between the plates of capacitor B. (i) The dielectric slab is placed inside. A as shown in figure (a). A is then charged to a potential difference of 110V. Calculate the capacitance of A and the energy stored in it. The battery is disconnected and then the dielectric slab is moved from A. Find the work done by the external agency in removing the slab from A. (iii) The same dielectric slab is now placed inside B, filling it completely, The two capacitors A and B are then connected as shown in figure(c). Calculate the energy stored in the system.

The resistance of 0.5M solution of an electrolyte in a cell was found to be 50 Omega . If the electrodes in the cell are 2.2 cm apart and have an area of 4.4 cm^(2) then the molar conductivity (in S m^(2) mol^(-1)) of the solution is