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 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 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 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)

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) a) "Ionic mobility of " K^(+) " is " 10^(-3)cm^(2)sec^(-1)"volt"^(-1) b) "The speed of" K^(+) is 10^(-3)cmsec^(-1) c) "Distance traveled by" K^(+) in 5xx10^3 sec is 5cm d) "The potential gradient is 1.0 volt" cm^(-1)

The molar ionic conductance at infinite dilution of Ag^(+) is 61.92xx10^(-4)Smd^(-1)m^(2) at 25^(@)C the ionic mobility of Ag^(+) will be